EP1434300A2 - Broadband antenna with a 3-dimensional casting part - Google Patents

Abstract

The device has a radiator element with as three-dimensional cast part arranged in front of a conducting reflector (13). The cast part has at least two planes of symmetry (15.1,15.3), is conducting and has a closed peripheral structure (11) with alternating constrictions and expansions and at least two attachment elements (12.1,12.2) connected to the reflector. At least one attachment element is used to electrically stimulate the radiator element. AN Independent claim is also included for the following: (a) a group antenna with several inventive antennas.

Description

The present invention relates to antennas that include a Include radiation element, which is arranged in front of a reflector surface.

Crossed dipole antennas for generating linear or circular Polarizations are known. A crossed dipole antenna is from the article "A wide-band aerial system for circularly polarized waves, suitable for ionospheric research ", G.J. Phillips, IEE Proc., Vol. 98 III, 1951, pp. 237-239. Turnstile antennas are described in various U.S. patents. An example is shown in U.S. Patent No. 2,086,976, issued in 1935. The one shown Antenna comprises a mast on which several crossed antennas are arranged are. There are also numerous textbooks dealing with turnstile antennas deal.

To improve the directivity, the antenna elements often arranged in front of a metallic reflector surface. This approach is known and is used in the following two antennas. A dual

Polarized dipole antenna is US Pat. No. 6,313,809 (corresponds essentially to German Offenlegungsschrift DE 198 60 121 A1) from Kathrein. This distinguishes this dipole antenna from that it consists of a number of individual dipole elements that precede a reflector are arranged. The dipole elements are in plan view as Arranged dipole square and each dipole element is symmetrical Line fed individually.

A dual polarized multi-range dipole antenna is the US patent US 6,333,720 from Kathrein.

The bandwidth of a dipole antenna can be improved by thick dipoles or so-called bow-tie dipole structures used. Such a broadband dipole antenna is from the article "Broadband half-wave dipole ", M.C. Bailey, IEEE Trans. Antennas Prop., Vol. 32, 1984, Pp. 410 - 412 known. A broadband antenna with a thick dipole structure is in the Antenna Engineering Handbook, R.C. Johnson and H. Jasik, editors, 2. Edition, McGraw Hill, 1984, mentioned on pp. 28-11.

It is a problem with the known antenna arrangements which are used in the Field of communication and in particular mobile communication that the antennas are expensive and heavy. That leads to expensive and complicated group antennas.

Based on the prior art mentioned at the outset the task of creating a broadband dipole antenna that is simple and is inexpensive.

It is another object of the invention to provide a dipole antenna which is suitable for installation in a group antenna.

According to the invention, an antenna with a radiation element is prepared placed in front of a conductive reflector and a three-dimensional Casting includes. The casting has at least two Levels of symmetry, is conductive and has a closed Circular structure with alternating constrictions and Bulges. The orbital structure preferably spans an imaginary surface that is intersected by the planes of symmetry of the casting. There are at least two fasteners are present, which are essentially extend perpendicular to the surface of the conductive reflector and at two Bases - which are preferably but not necessarily on intersection lines the planes of symmetry with the imaginary surface lie - the circular structure wear. The at least two fastening elements run essentially parallel to each other and lie in the cylinder surface of an imaginary cylinder, the longitudinal axis of the cylinder perpendicular to the surface of the conductive reflector stands. The planes of symmetry intersect in one common straight line that coincides with the longitudinal axis of the cylinder.

The fastening elements are preferably symmetrical Reference to the planes of symmetry, or in the limit in the planes of symmetry. On their (lower) ends are the fasteners with the conductive Connected reflector, at least one of the fastening elements for electrical excitation of the beam element is used.

Further embodiments according to the invention are the dependent claims 2 to 13.

According to the invention, a group antenna with several Beam elements provided as claimed in claim 14. Further Embodiments according to the invention are the dependent claims 15 and 16.

Fig. 1A

eine Antenne gemäss Erfindung in einer schematischen Seitenansicht;

Fig. 1B

die Antenne gemäss Fig. 1A in einer schematischen Draufsicht;

Fig. 1C

einen Ausschnitt der Antenne gemäss Fig. 1A in einer schematischen Schnittansicht;

Fig. 1D

einen Ausschnitt eines weiteren Befestigungselements gemäss Erfindung in einer schematischen Schnittansicht;

Fig. 2A

eine weitere Antenne gemäss Erfindung in einer schematischen Draufsicht, wobei die Abstrahlung vertikal linear polarisiert ist;

Fig. 2B

eine weitere Antenne gemäss Erfindung in einer schematischen Draufsicht, wobei die Abstrahlung horizontal linear polarisiert ist;

Fig. 2C

eine weitere Antenne gemäss Erfindung in einer schematischen Draufsicht, wobei die Abstrahlung 45° linear polarisiert ist;

Fig. 3A

eine Versorgungsschaltung gemäss Erfindung, die sich auf der Rückseite eines Reflektors befindet;

Fig. 3B

eine weitere Versorgungsschaltung gemäss Erfindung, in schematischer Blockansicht;

Fig. 3C

eine weitere Versorgungsschaltung gemäss Erfindung, in schematischer Blockansicht;

Fig. 4A-4F

verschiedene regelmässige Umlaufstrukturen, gemäss Erfindung;

Fig. 5A-5B

verschiedene unregelmässige Umlaufstrukturen, gemäss Erfindung;

Fig. 6

einen Ausschnitt eines Befestigungselements gemäss Erfindung in einer schematischen Seitenansicht;

Fig. 7

eine Gruppenantenne gemäss Erfindung in einer schematischen Draufsicht.

The invention is described in detail below with reference to exemplary embodiments illustrated in the drawings. Planes of symmetry are indicated in the drawings by dashed lines and imaginary areas by dotted lines, where this is necessary for a clearer illustration of the invention. Show it:

Fig. 1A

an antenna according to the invention in a schematic side view;

Figure 1B

1A in a schematic plan view;

1C

a section of the antenna of FIG 1A in a schematic sectional view.

Figure 1D

a section of another fastener according to the invention in a schematic sectional view;

Figure 2A

a further antenna according to the invention in a schematic plan view, wherein the radiation is polarized vertically linear;

Figure 2B

a further antenna according to the invention in a schematic plan view, the radiation being horizontally linearly polarized;

Figure 2C

a further antenna according to the invention in a schematic plan view, the radiation being 45 ° linearly polarized;

Figure 3A

a supply circuit according to the invention, which is located on the back of a reflector;

Figure 3B

a further supply circuit according to the invention, in a schematic block view;

Figure 3C

another supply circuit according to the invention, in a schematic block view;

4A-4F

various regular circulation structures, according to the invention;

5A-5B

various irregular circulation structures, according to the invention;

Fig. 6

a detail of a fastener according to the invention in a schematic side view;

Fig. 7

a group antenna according to the invention in a schematic plan view.

Detailed description:

In the following, terms are explained and defined that are used in the Description and the claims appear several times.

The following text talks about castings. According to the invention are to be understood under the term cast part molded parts, which in (automatic) Injection molding processes were produced. This will be thermoplastic Processable plastics processed using an injection molding process.

According to the invention, various plastic injection molding compounds can be used can be used to manufacture the molded parts. Some Examples of plastics are listed below: PA (polyamide); POM (Polyacetal); PET (polyethylene terephthalate); PS (polystyrene); TPE (thermoplastic polyester elastomer); LCP (Liquid Crystal Polymer); PBT (Polybutylene terephthalate); SB (styrene / butadiene); SAN (styrene acrylonitrile); SECTION (Acrylic Buadien styrene); PPE (modified polyether); PVC (polyvinyl chloride); CA (Cellulose acetate); CAB (cellulose acetate butyrate); CP (cellulose propionate); PE (Polyethylene); PP (polypropylene); PMMA (polymethyl methacrylate); PC (Polycarbonate); PSO (polyarylsulfone); PES (polyether sulfone); PEI (Polyetherimide); PAI (polyamideimide); PVDF (polyvinylidene fluoride).

Polymer blends can also be used. This is what it is about are combinations of two or more miscible polymers. blending is a process, a mixture, or a reaction of two or more Polymers to get improved product properties.

Modified plastics with filler particles can also be used be used, which are the construction of adhesive or electrodeless easier galvanically deposited metal layers. The filler particles can be made from electrically conductive metals (e.g. palladium) or from electrically non-conductive metal pigments exist, as in spray paints for electromagnetic shielding can be used. These metal pigments serve as a catalyst for the electrodeless deposition of a metallic Starting layer, which can then be galvanically reinforced. The Spray paint reaches only a limited and strong of the plastic material dependent adhesive strength. By embedding the particles in the plastic mass a significant improvement in the adhesive strength is achieved by the particles are only superficially exposed through a short pickling process, otherwise but remain enclosed by the plastic mass.

Instead of plastic, metals can also be used to manufacture the cast parts be used. Aluminum is particularly suitable Aluminum injection molding process can be processed. Are also suitable Molded parts made of zinc, magnesium (e.g. producible using thixo injection molding), or made of titanium aluminum.

Plastic injection molded parts can also be used or contain several metals.

The molded parts are characterized by the fact that a minimum of Postprocessing effort is necessary. In addition, the dimensions of the Moldings very precise.

Reflectors can be used, preferably one have conductive surface. This conductive surface can be grounded. The reflector surface can be flat or curved.

A first antenna 10 according to the invention is shown in FIGS. 1A and 1B. An antenna 10 according to the invention comprises a three-dimensional one Beam element, which is arranged in front of a conductive reflector 13. The The blasting element is a cast part. The casting is designed to be conductive Antenna can be used. For this purpose, the casting can be made with either be provided metallic layer that completely or partially covers the casting. Alternatively, the cast part can comprise electrically conductive particles, which are thus integrated into one Guest material are embedded that the casting at least in the Surface area is electrically conductive. The casting can also be made from Be made of material that is conductive in itself. Metals or are well suited Metal alloys.

The cast part also includes a closed circulation structure 11 alternating constrictions and bulges. The Circular structure 11 has the shape of a cross in the example shown an imaginary surface 14 spanned by at least two planes of symmetry is cut. The planes of symmetry intersect the imaginary surface 14 and thus form intersection lines 15.1 and 15.3, as shown in FIG. 1B with dashed lines Lines shown. The actual circulation structure 11 points in addition to the two intersection lines 15.1 and 15.3 also two axes of symmetry on the are designated in Fig. 1B with 15.2 and 15.4.

There are at least two fastening elements 12.1, 12.2 provided which is substantially perpendicular to the surface of the conductive Extend reflector 13. The fastening elements 12.1, 12.2 are on two Bases - those on the intersection line in the embodiment shown 15.1 lie - connected to the circulation structure 11. The at least two Fastening elements 12.1, 12.2 run essentially parallel to one another and lie in the cylindrical surface of an imaginary cylinder 9, the Longitudinal cylinder axis 8 is perpendicular to the surface of the conductive reflector 13. The mentioned planes of symmetry 15.1 and 15.3 intersect in one common line of intersection, which coincides with the cylinder longitudinal axis 8.

As mentioned, the fastening elements 12.1, 12.2 are on two Bases that lie on the intersection line 15.1 with the circular structure 11 connected and carry the circulation structure 11. At their other ends 16 are the fasteners 12.1, 12.2 connected to the reflector 13. additionally at least one of the fastening elements 12.1, 12.2 serves for the supporting function for electrical excitation of the beam element.

Overall, the radiating element has a mushroom-like shape in which the area 14 spanned by the circular structure 11 the mushroom hat and the imaginary cylinder 9 form the foot of the mushroom. The comparison of the Beam element with a mushroom-like shape only serves the better Illustration of the invention.

Fastening elements, which are a particularly suitable have a columnar structure. The fastening elements are preferably one integral part of the circulation structure 11. In this case, both the Circumferential structure 11 as well as the fastening elements in one piece and thus without additional assembly steps and assembly tolerances are produced.

The fasteners are preferably cylindrical Shape with a round cross-section, but can also have other cross-sectional shapes exhibit.

In a preferred embodiment, the Fasteners on the lower end of fasteners that allow it the circulation structure 11 together with the fastening elements 12.1, 12.2 on the Attach reflector 13. For this purpose, the fasteners 12.1, 12.2 for example with a snap mechanism or one Be provided connector that allow the fasteners Insert 12.1, 12.2 into holes in the reflector 13 and snap them into place. Instead of a snap connection, screw, solder or other - connections are provided. Connections that are next to one are ideal mechanical connection also establish an electrically conductive connection.

When connecting the fasteners 12.1, 12.2 with the It should be noted that the reflector 13 on the front 17.2 (i.e. on the side of the reflector 13 which faces the circulating structure 11) is made conductive, as indicated in Fig. 1C. At least one of the Fastening elements 12.1 must thus be able to be fastened in the reflector 13, that there is no conductive connection to the conductive side 17.2 of the reflector 13 forms. Otherwise, both fasteners 12.1, 12.2 would be over the conductive reflector 13 shorted and the antenna could not can be controlled.

An example of the attachment and electrical excitation of a the fasteners 12.1 is shown in Fig. 1C. The fastener 12.1 comprises a cylinder, the wall 19.1 of which has a conductive layer 18 is provided. The reflector 13 is made of an electrically conductive layer 17.4 formed on the front 17.2 of a dielectric plate 17.5. The Reflector 13 has a hole in which the lower end 16 of the Fastening element 12.1 is performed. A falling out of the Fastening element 12.1 is prevented by nose-like projections 19.2, which enable the assembly process by compression. A distance between the conductive surface 17.4 and the fastening element 12.1 prevents one Short circuit of the supply signal. The feed signal is, for example, by a strip line is created on the back of the reflector 13, which in is electrically conductive connection to the conductive layer 18.

A particularly advantageous example of the attachment and the Electrical excitation of one of the fasteners 12.1 is shown in Fig. 1D. The fastening element 12.1 comprises a cylinder, the wall 19.1 of which a conductive layer 18 is provided. The reflector 13 is made from a electrically conductive layer 17.4 on the front 17.2 of a dielectric Plate 17.5 formed. The reflector 13 has a hole in which the lower End 16 of the fastener 12.1 is guided, a mechanical Stop is formed by a gradation 19.3 of the cylinder diameter. On Falling out of the fastener 12.1 is by nose-like projections 19.2 prevented, which allow the assembly process by compression. A prevents annular recess 17.7 of the electrically conductive layer 17.4 a short circuit in the supply signal. The feed signal is given by a Strip line 17.6 formed on the back of the reflector 13, which in is electrically conductive connection to the conductive layer 18. In the in Fig. 1D, the particularly advantageous embodiment shown is the stripline 17.6 and by the annular recess 17.7 of the electrically conductive Layer 17.4 separated area 17.8 by a by the reflector 13th passing electrically conductive layer 17.9, a so-called Vias, interconnected.

Numerous other types of fastening are conceivable (e.g. using ring-shaped insulator insert or bare hole) to make a contact between the fastener and the conductive surface of the reflector avoid.

In a special embodiment, this is the casting facing side 17.2 of the reflector 13 made conductive. It can also do that rear side 17.1 be made conductive. In addition, the leading side of the reflector 13 completely or partially covered with a non-conductive layer be to protect the reflector 13 from environmental influences. This non-conductive Layer can be a plastic layer that is used for the electromagnetic fields is transparent.

Some of the antennas according to the invention are characterized by that the imaginary surface 14 spanned by the circular structure 11 in the Extends substantially parallel to the reflector 13. The imaginary surface 14 can be flat or curved.

The reflector 13 can be slightly curved.

The advantages of the invention are particularly evident when the reflector 13 on the side 17.1, which faces away from the casting, a Has supply circuit. This supply circuit can be used for dining the antenna. For this purpose the Supply circuit include a network, which has a supply input connects with the two fasteners 12.1, 12.2 so that they can be controlled in opposite phases.

Such an antiphase control is schematic in FIG. 2A shown. The antenna 20 comprises a circular structure 21 similar to that in FIG. 1A and 1B, however, four fastening elements 22.1 to 22.4 are provided. Both the two fasteners 22.1 and 22.3 as well as the two Fastening elements 22.2 and 22.4 are driven in opposite phases. The two fastening elements 22.1 and 22.2 are excited in phase. As indicated by the three arrows in Fig. 2A, arises from the symmetrical design of the beam element 21 an E-field in the x-direction is linearly polarized (vertical polarization).

Another control is shown schematically in FIG. 2B. Again, both the fasteners 22.1 and 22.3 as also the two fasteners 22.2 and 22.4 each in opposite phase driven. Now, however, the two fasteners 22.1 and 22.4 excited in phase. As indicated by the three arrows in Fig. 2B, an E field is created due to the symmetrical design of the beam element 21, which is linearly polarized in the y direction (horizontal polarization).

A simplified control is shown schematically in FIG. 2C. The fastener 22.4 becomes out of phase with the fastener 22.2 excited, as indicated by the arrow in Fig. 2C. Through the Symmetrical design of the beam element 21 creates an E-field that is -45 ° is linearly polarized (-45 ° slant polarization). Analogously to FIG. 1B, in this application, the fasteners 22.1 and 22.3 without essential effects on the antenna function are omitted, however, which may affect mechanical stability. The Fastening elements 22.1 and 22.3 can in a further modification of the Excitation to be electrically connected to the reflector 13 or 23. One too with minor restrictions (this time the electrical properties of the Antenna) accompanying excitation variant sees the exclusive excitation one of the fasteners 22.2, 22.4 before, the other Fastening element is electrically connected to the reflector 13 or 23. The associated deviation from the ideal-symmetrical Polar pattern is permissible, especially when used as Radiating element in a group antenna.

Depending on the control, circular or elliptical can also be used Polarizations, for example analogous to Fig. 2A or 2B by phase-shifted excitation of the fastener pairs 22.1, 22.3 and 22.2, 22.4 can be achieved.

A network 30 according to the invention is shown in FIG. 3A as an example. The network shown is on the back of a reflector surface and has two supply inputs 32.1 and 32.2. There are four goals 31.1 to 31.4 provided with the fasteners (not shown in Fig. 3A) of the Beam element are connected. Between the feed input 32.1 and A 180 ° hybrid 33.1 is arranged in the two ports 31.4 and 31.2. Between the supply input 32.2 and the two ports 31.3 and 31.1 is another 180 ° hybrid 33.2 arranged. The 180 ° hybrid 33.2 includes a λ / 4 Delay line between points A and C and a 3λ / 4 Delay line between points A and B. The line between B and C in turn represents a λ / 2 delay line. The delay lines are designed for the center frequency of the feed signals. Ports 31.1 to 31.4 are via line sections with the two 180 ° hybrids 33.1 and 33.2 connected, each causing the same phase shift. The network 30 ensures that the diagonally opposite ports are 180 ° out of phase, that is, out of phase, are controlled, whereby the the other two ports are each in a virtual short circuit level. The Feed inputs 32.1 and 32.2 thus have a high mutual Decoupling on. This gives a particularly pure polarization of the radiated wave, or a strongly suppressed Cross-polarization component. There are other embodiments of 180 ° power dividers for feeding those lying on the corners of a square Supply inputs 31.1 to 31.4 of FIG. 3A possible, their stripline layout can be done according to the following generalized rule to the greatest possible To achieve electrical symmetry: For example, you start with the Definition of a connection point B on the 31.1 through the supply inputs and 31.4 given straight line. In compliance with the same electrical line length between the feed input 31.1 and Connection point B on the one hand and the feed point 31.3 and the connection point C on the other hand, the position of the connection point C can be chosen freely. The Network input corresponding to the connection point A of the 180 ° hybrid in FIG. 3A can be positioned anywhere. The second's stripline layout The 180 ° power divider can now be obtained by two mirror images: in the first Step mirrors the layout of the first 180 ° power divider on the Axis of symmetry, which feed points 31.1 and 31.2 in the feed points 31.4 and 31.3 transferred. In the second step you just mirror the layout of the Connection line between the feed point 31.4 and connection point B of the second 180 ° power divider around the axis 31.1 - 31.4.

If you now feed the supply input 32.2 with an RF signal S2 (t), there is a signal at port 31.3 with a phase angle of 0 ° and at Port 31.1 receives a signal with a phase angle of 180 °. With the network 30 shown you can generate a push-pull signal from an RF signal S2 (t). The Beam element builds a + 45 ° slant polarization in the described supply on. Alternatively, the sole supply of the supply input 32.1 generates Beam element has a -45 ° slant polarization.

For example, if you feed the input 32.1 with a RF signal S1 (t) and the supply input 32.2 with an RF signal S2 (t), the both are in phase with each other, there is a signal at the gate 31.2 with the Phase 0 °, at gate 31.3 a signal with phase 0 °, at the gate 31.4 a signal with the phase angle 180 ° and at the gate 31.1 a signal with the Phase angle 180 °. With the network 30 shown, one can therefore have two RF signals S1 (t) and S2 (t) each generate a phase excitation. The Beam element builds a horizontal one with the described feed Polarization on.

If you control the supply inputs 32.1 and 32.2 in phase opposition (i.e. S1 (t) is 180 ° out of phase with S2 (t)), one is built vertical polarization.

To achieve circular polarization, the two Power inputs 32.1 and 32.2 controlled so that S1 (t) compared to S2 (t) is phase shifted by + 90 ° or -90 °. They can also be elliptical Generate polarizations if the phase shift occurs at + 90 ° or - 90 ° Amplitude of S1 (t) is different from the amplitude of S2 (t) or / and Phase shift deviates from 0 °, + 90 °, -90 ° and 180 °.

It is an advantage of the network shown as an example that the Polarization properties of the antenna without changing the radiation element only are adjustable by a suitable control. Depending on the feed to the Feeding inputs is thus the polarization of the radiation element radiated signals can be influenced.

The control of the beam element can also be done by others Supply circuits, for example (combination) networks and Delay lines. The supply circuit can be in planar, coaxial or waveguide line technology.

The supply circuit can be designed so that it is off one signal (e.g. S1 (t)) up to four different control signals for Driving the radiation element generated.

Another example of a supply circuit is in Fig. 3B shown. The supply circuit has a supply input 34, the a signal S1 (t) is supplied. A divider 35 follows, the first of which Output signal is applied to a gate 37.4. The second output signal of the Divider 35 is phase shifted via a 180 ° phase shifter 36 and then a gate 37.2 fed. The two ports 37.1 and 37.3 are grounded. The Supply circuit in Fig. 3B enables a single linear polarization.

A third example of a supply circuit is in Fig. 3C shown. The supply circuit has a supply input 34, the a signal S1 (t) is supplied. A 180 ° hybrid 39 feeds two Connecting lines 40a, 40b in push-pull. Connecting line 40a connects the neighboring gates 38.1 and 38.2, connecting line 40b the neighboring ones Goals 38.3 and 38.4. Preferably, the connecting lines 40a and 40b each of two identical, mirror-symmetrical to the connection point of the 180 ° hybrids 39 arranged arms and are identical.

• Die Umlaufstruktur ist eine geschlossene Umlaufstruktur mit einander abwechselnden Einschnürungen und Ausbuchtungen.
• Die Umlaufstruktur spannt eine imaginäre Fläche auf, die durch mindestens zwei Symmetrieebenen des Gussteils geschnitten wird.
• Die Symmetrieebenen schneiden sich in einer gemeinsamen Schnittgerade, die in etwa senkrecht zum Reflektor verläuft.

According to the invention, the circular structure can have any shape that meets the following conditions:

• The circular structure is a closed circular structure with alternating constrictions and bulges.
• The circular structure spans an imaginary surface that is cut through at least two planes of symmetry of the casting.
• The planes of symmetry intersect in a common line of intersection, which is approximately perpendicular to the reflector.

Has a particularly advantageous embodiment of the circulation structure four wing elements, which are arranged symmetrically. Are the farthest points (bulges) of the orbital structure which are at a distance from one another half wavelength apart, acts the same as two crossed dipole elements. The two planes of symmetry of the casting are preferably perpendicular to each other.

Each dipole element of the crossed dipole antenna is preferred fed symmetrically.

Various regular circulation structures are shown in FIGS. 4A to 4D schematically indicated, it should be noted that there are numerous others There are shapes that are also suitable as a circular structure. This regular Orbital structures have four levels of symmetry.

Further circulation structures according to the invention, now with three Planes of symmetry are shown in Figures 4E and 4F. The orbital structure of Fig. 4E has three wing elements, which are rotated by 120 ° against each other are arranged. Are signals of the same amplitude at the three constrictions and fed with 0 °, 120 ° and 240 ° phase shift, you get on the right or circularly polarized radiation on the left. 4F also shows a Generation of circularly polarized radiation suitable circulation structure.

Various irregular orbital structures are in the figures 5A and 5B schematically indicated. These irregular circulation structures have at least two planes of symmetry and are preferred with one Circuit driven according to Fig. 3C. Another beneficial one The use of the circulation structures in FIGS. 5A and 5B is the simplified one Generation of circular polarization by applying phase signals in phase opposition two opposing constrictions.

The circulation structure is preferably designed such that Wing elements are present which result in at least one resonance circuit, which is burdened by the radiation.

The fastening elements are preferably designed such that transformers from the excitation impedances to the Result in resonator impedances.

The fasteners designed as a transformer have in an advantageous design on such a large diameter that it against the conductive reflector surface represent an interfering capacitive load. To the to reduce capacitive load on the control circuit can Example fasteners are used, which are towards the reflector rejuvenate that there is an inductive initial stage. An example of one such fastener is in Fig. 6 in a schematic side view shown. A fastener is shown having a first cylindrical Has area 62 which has a first diameter. At the bottom of the a second cylindrical area 61 is provided in the first area 62 thereof Diameter is smaller than the diameter of the first area 62. The first The area does not necessarily have to be centered on the second area be arranged. The fastener shown is designed so that it is easy to remove from the mold after casting.

According to the invention, the radiation characteristic is essentially determined by the distance of the beam element from the reflector. As The distance of the beam element from the reflector is preferred chosen between 1/10 and 1/3 of the emitted wavelength in air.

According to the invention, a metallic screen arrangement can be provided, all, part or not at all with the senior Reflector surface is connected. The screen arrangement preferably has the same planes of symmetry as the beam element surrounded by them. she can be in one piece or taking into account the planes of symmetry from a corresponding number of individual elements. A special one advantageous arrangement consists of a circumferential electrically conductive Wall, which depending on the desired beam concentration below or above the point of the most distant from the reflector surface 23 Beam element ends. The screen arrangement can also be used to the mutual coupling between neighboring Reduce beam elements in a group antenna.

A group antenna according to the invention is characterized in that that several antennas are arranged in rows and columns. A exemplary array antenna 70 is shown in FIG. 7. The group antenna 70 comprises two columns with three antennas 71 each. The antenna radiation elements 71 are arranged rotated 45 degrees in the example shown. The Beam elements can also have any other orientation. About that In addition, the horizontal distance may be necessary or useful to choose between the individual antennas other than the vertical distance. A reflector surface 73 is arranged behind the steel elements. It is one Supply matrix (not visible in Fig. 7) available, which allows the Combine antennas in rows and / or columns. Preferably each antenna 71 comprises a beam element and an individual one Supply circuit. The supply matrix mentioned then represents the necessary connections between total inputs of the group antenna and the supply inputs of the supply circuits. The Supply matrix, the supply circuit and the supply signal is in the example shown so that there is a linear polarization in vertical direction results, as indicated by the E-fields.

The antennas described and shown are particularly suitable for operation in the gigahertz frequency range, with the supply inputs Signals are applied that have a center frequency that is greater than Is 1 GHz. The antennas are particularly suitable for mobile radio and others Communication systems. The upper frequency limit can be about 25 GHz, where the diameter of the beam elements according to the invention is about 5 millimeters assumes and the distance between the circulation structure and the reflector plane can be smaller than 3 millimeters. In the range between about 10 GHz and 25 GHz, the beam elements can be designed as SMD (Surface Mounted Device), which is directly connected to a dielectric boards carrying the supply circuits are soldered on. The lower ends 16 of the fasteners 12.1 to 12.4 are therefor preferably with a galvanic that is easily wettable by the solder used Provided surface, whereas the remaining three-dimensional structure of the Beam element is preferably covered by a solder-repellent layer. This can be done, for example, by dip painting, plasma coating with a dielectric layer or by selectively depositing one from the used solder wettable metal are generated. The reflector surface is preferably by a large-area conductive layer on the Beam elements facing away from the dielectric plate is formed. A A particularly advantageous method for solder assembly is the use of Solder balls with low mechanical tolerances, which with professional, from the Ball Grid Array (BGA) technology known dimensioning a reliable Cause self-centering of the blasting element.

It is an advantage of the invention that the beam elements are large Number of pieces can be produced, whereby great shape accuracy is guaranteed. The The term shape retention expresses that a low tolerance representation of the Tool cavity can be achieved through the molded part. The beneficial one-piece design of the casting forming the blasting element guaranteed in particular, the exact adherence to achieve a high Cross polarization decoupling necessary mirror symmetries. Will that Beam element made up of several (preferably identical) parts composed, this property is due to the assembly tolerances harder to achieve. Typically the weight of a radiating element very low. Depending on the material and frequency range, a weight can be achieved be that for use at cellular frequencies below 20g lies.

The single and group antennas described are very good compact. If the supply circuit is provided on the reflector, the wiring effort is significantly reduced.

Claims (16)

Antenna (10; 20; 70) with a radiation element, which is arranged in front of a conductive reflector (13; 23; 73), characterized in that the radiation element comprises a three-dimensional cast part, which has at least two planes of symmetry (15.1, 15.3), which is made conductive and has a closed circular structure (11; 21; 71) with alternating constrictions and bulges, the circular structure (11; 21; 71) spanning an imaginary surface (14) which is separated from the at least two planes of symmetry (15.1, 15.3) is cut, and which has at least two fastening elements (12.1 to 12.4) which extend substantially perpendicular to the imaginary surface (14) and which support the circumferential structure (11; 21; 71) at points lying on at least one of the planes of symmetry (15.1, 15.3) and at their ends (16) are connected to the reflector (13), at least one of the two fastening elements (12.1, 12.2) being used to electrically excite the radiation element. Antenna according to Claim 1, characterized in that the reflector (13; 23; 73) comprises a flat surface which has a conductive side (17.2) which faces the cast part. Antenna according to claim 1 or 2, characterized in that the imaginary surface (14) spanned by the revolving structure (11; 21; 71) extends essentially parallel to the reflector (13; 23; 73). Antenna according to claim 1 or 2, characterized in that the imaginary surface (14) spanned by the revolving structure (11; 21; 71) is flat or curved. Antenna according to one of the preceding claims, characterized in that the casting is a plastic casting, which is provided in whole or in part with a conductive layer, or that the casting is a metallized plastic injection molding. Antenna according to one of claims 1 to 4, characterized in that the casting is a metal casting. Antenna according to one of the preceding claims, characterized in that the reflector (13; 23; 73) has a supply circuit (30) on the side (17.1) which faces away from the cast part. Antenna according to Claim 7, characterized in that the supply circuit comprises a network in order to connect two supply inputs to the two fastening elements (12.1, 12.2) in such a way that they can be driven in opposite phases. Antenna according to claim 8, characterized in that the supply circuit is designed such that, depending on the supply at the supply inputs, the polarization of the signals emitted by the radiation element can be influenced. Antenna according to claim 7, characterized in that the supply circuit consists of two adjacent fastening elements (22.1, 22.2 or 22.4, 22.3 or 22.1, 22.4 or 22.2, 22.3) connecting in-phase power dividers, which in turn are counter-phase by a balun (33.1, 33.2) are controllable. Antenna according to claim 7, characterized in that the supply circuit is implemented in planar, coaxial or waveguide line technology on the side (17.1). Antenna according to one of the preceding claims, characterized in that the cast part is surrounded by a screen arrangement, which is preferably metallized. Antenna according to one of the preceding claims, characterized in that the at least two fastening elements lie in the cylindrical surface of an imaginary cylinder (9), the longitudinal axis of the cylinder (8) of which is perpendicular to the conductive reflector (13; 23; 73). Group antenna with several antennas according to one of the preceding claims, characterized in that the antennas are arranged in rows and columns and a supply matrix is provided, by means of which the antennas can be combined in rows and / or columns. Group antenna according to claim 14, characterized in that each of the antennas has a supply circuit with supply inputs. Group antenna according to claim 15, characterized in that connections between the total inputs of the group antenna and the supply inputs of the supply circuits can be established by the supply matrix.

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