DE102005003685B4 - Antenna with reflector - Google Patents

Abstract

Antenna with at least one reflector (12) and at least one radiating element (2-6, 22-24, 2'-6 ', 22'-24'), which is arranged at a distance from the flat reflector (12) and which has at least one first Radiant body (7, 7 '), the geometry of which corresponds to a section of a three-axis ellipsoid, with all three semi-axes (9, 10, 11, 11 ") of different lengths and the shortest of the three semi-axes (11") being perpendicular to the Surface of the flat reflector (12) runs.

Description

The invention relates to an antenna with a reflector.

Reflector antennas in which the incident radiation is reflected onto the actual radiating element of the antenna by means of a reflector are known. It is also known to use an ellipsoid as a radiating element. Such an ellipsoid of revolution is preferably used as a radiation element in broadband applications. Due to the rotational symmetry of the ellipsoid and the resulting minimum distance and the interactions with a reflector, however, the combination of a reflector with an ellipsoidal radiating element is difficult. In particular, for a broadband application it is then necessary to provide additional loading elements with which impedance matching takes place.

Such discrete components for impedance matching, however, result in a reduction in sensitivity due to their damping effect.

Regarding the state of the art, refer to DE 195 22 436 A1 referenced, from which it is known to arrange several dipoles around a support mast.

The object of the invention is to create an antenna which can be used in a broadband frequency spectrum, in which case impedance matching by means of discrete components can be dispensed with.

The object is achieved by the antenna according to the invention with the features of claim 1.

The antenna according to the invention consists of at least one reflector and at least one radiating element. The radiating element is arranged at a distance from the reflector. The radiating element consists of at least one first radiating body, the geometry of this first radiating body corresponding to a section of a three-axis ellipsoid. In this three-axis ellipsoid, all of the three semi-axes are of different lengths. The combination of a reflector with a radiation body whose geometry corresponds to a section of an ellipsoid allows the broadband function of the antenna to be retained without impedance correction by discrete components being necessary. The slight change in the impedance in the frequency band is due to the interaction between the reflector and the radiating body arranged at a distance from it. The use of only a section of the ellipsoid reduces the change in impedance over the frequency, so that, in contrast to an arrangement with a complete ellipsoid, additional discrete components can be dispensed with.

Advantageous developments of the antennas according to the invention are set out in the dependent claims.

It is particularly advantageous to position the radiator with respect to the reflector so that its closed side is oriented towards the side facing away from the reflector, i.e. the center of the three-axis ellipsoid is on the side of the radiator facing the reflector. For the geometry of the ellipsoidal radiating body, it has been found to be particularly advantageous to choose all three semiaxes of the three-axis ellipsoid of different lengths, the shortest of the three semiaxes particularly preferably running perpendicular to the reflector surface. This results in an arrangement in which the ellipsoidal geometry of the radiating body is flattened towards the reflector.

A particularly advantageous section of the three-axis ellipsoid is obtained when the three-axis ellipsoid is cut out by a first cut surface and a second cut surface arranged approximately perpendicular thereto. The first cut surface and second cut surface used do not necessarily have to be flat surfaces. However, it is particularly advantageous to use a flat first surface and a flat second surface and to make the cuts in two of the planes of symmetry of the ellipsoid. The resulting radiant body thus corresponds to a quarter of the complete ellipsoid.

With regard to the reflector, the first radiating body is preferably arranged in such a way that the first cut surface, which extends along the longest semi-axis, is arranged parallel to the reflector surface.

According to a further particularly preferred embodiment, the radiating element is a dipole radiator. In addition to the first radiator, the dipole radiator comprises a second radiator which is also a section of a three-axis ellipsoid. In particular, the ellipsoidal geometries correspond to one another, i. H. the three semi-axes of the first jet body and the corresponding semi-axes of the second jet body are identical in pairs.

The two radiating bodies of the dipole radiator are preferably arranged relative to one another in such a way that a semiaxis of the first radiating element and the corresponding semiaxis of the second radiating element and the surface normal of the reflector are in one common first level. This semiaxis of the first jet body and the corresponding semiaxis of the second jet body can also enclose an angle other than 0 °.

The first radiant body and the second radiant body are furthermore arranged symmetrically with respect to a second plane. The second plane is perpendicular to the first plane and the reflector surface. The closed ends of the radiant bodies are each oriented in the direction of the second plane.

According to a further preferred embodiment, the reflector forms a surface that is closed about a reflector axis, with several dipole radiators being arranged along the circumference of the closed reflector surface. The reflector axis falls z. B. with an axis of an antenna tower on a ship, so that a plurality of dipole radiators is arranged around this antenna tower. The multiple dipole radiators are preferably arranged with their longitudinal axis parallel to the reflector axis. In the axial direction with respect to the reflector axis, the dipole radiators are positioned identically, so that the dipole radiators, each of the same design, are arranged on a common horizontal plane. For a diameter of about 60 cm to 110 cm, with a required frequency range of about 180 MHz to 600 MHz, particularly good properties for eight dipole radiators result.

The dipole radiators are spaced apart from their neighboring dipole radiators along the circumference of the reflector surface. In at least some of these distances, a separating plate is arranged between the dipole radiators, which sheet metal extends in the axial direction and is directed radially outward from the reflector.

The reflector axis usually extends in the vertical direction. With this arrangement it is particularly advantageous to provide a horizontally extending roof plate at a distance from the dipole radiators in the axial direction. The roof plate extends outwardly from the reflector in the radial direction. It is particularly advantageous to provide a footplate in addition to this roof plate, which is formed on the side of the dipole radiators facing away from the roof plate and also at a distance from them and extends there in the radial direction outward from the reflector. It is particularly advantageous if the roof plate and the toe plate have an identical geometry and thus an antenna that is symmetrical to a horizontal plane results.

• 1 ein erstes Ausführungsbeispiel einer Antenne mit mehreren Dipolstrahlern in perspektivischer Darstellung;
• 2 eine schematische Darstellung zur Veranschaulichung der dreiachsigen ellipsoiden Grundform der Strahlkörper;
• 3 einen Schnitt durch die Antenne der 1;
• 4 ein zweites Ausführungsbeispiel der erfindungsgemäßen Antenne in perspektivischer Darstellung;
• 5 einen Schnitt durch die Antenne der 4;
• 6 eine Seitenansicht der bevorzugten Geometrie der Dipolstrahler des zweiten Ausführungsbeispiels;
• 7 eine Draufsicht eines Strahlkörpers des Dipolstrahlers aus 6;
• 8 eine Seitenansicht des zweiten Ausführungsbeispiels einer erfindungsgemäßen Antenne;
• 9 ein Verlauf des „Voltage Standing Wave Ratio (VSWR)“ in dem bevorzugten Frequenzband;
• 10 ein Messdiagramm des Antennengewinns in Abhängigkeit von der Frequenz;
• 11 eine Auswahl von Vertikaldiagrammen bei verschiedenen Frequenzen und
• 12 eine Auswahl von Horizontaldiagrammen bei verschiedenen Frequenzen.

Preferred exemplary embodiments of the antenna are shown in the drawing and are explained in more detail in the following description. Show it:

• 1 a first embodiment of an antenna with several dipole radiators in a perspective view;
• 2 a schematic representation to illustrate the three-axis ellipsoidal basic shape of the radiant body;
• 3 a section through the antenna of the 1 ;
• 4th a second embodiment of the antenna according to the invention in a perspective view;
• 5 a section through the antenna of the 4th ;
• 6th a side view of the preferred geometry of the dipole radiator of the second embodiment;
• 7th a plan view of a radiator of the dipole radiator 6th ;
• 8th a side view of the second embodiment of an antenna according to the invention;
• 9 a curve of the “Voltage Standing Wave Ratio (VSWR)” in the preferred frequency band;
• 10 a measurement diagram of the antenna gain as a function of the frequency;
• 11 a selection of vertical diagrams at different frequencies and
• 12 a selection of horizontal diagrams at different frequencies.

In the 1 is a first embodiment of an antenna 1 shown. The antenna 1 has several dipole radiators visible in the perspective view 2 , 3 , 4th , 5 and 6th as well as other concealed dipole radiators. In addition to those in the 1 visible dipole radiators are on the side of the antenna facing away in the illustration 1 further dipole radiators arranged. The dipole radiators are constructed identically and have a geometry that corresponds to a section of a three-axis ellipsoid.

The basic shape of such a three-axis ellipsoid is in 2 shown. In a Cartesian coordinate system, a three-axis ellipsoid is completely described by three semi-axes a, b, c. The ellipsoid is symmetrical to three planes of symmetry each formed from two axes of the coordinate system and to its center point M. .

The Indian 1 shown dipole radiators 3 has a first jet body 7th and a second jet body 8th on. For the sake of clarity, the geometry of all dipole radiators is shown below using the example of the dipole radiator 3 explained.

The first radiant body 7th of the dipole radiator 3 corresponds to a section of an ellipsoid with the three semiaxes 9 , 10 and 11 . The first radiator 7th The defining section of the ellipsoid is determined by a first cut surface and a second cut surface with which the ellipsoidal basic shape is cut. In the in the 1 illustrated embodiment, the first cut surface is a flat surface, which in the through the first semi-axis 9 and the second semi-axis 10 formed level lies. It becomes a first cutting edge 13 educated. The second cutting surface creates a second cutting edge 14th on the first radiator 7th educated. The second cut surface preferably intersects the first cut surface at an approximately right angle and thus lies approximately in the direction through the second and third semi-axes 10 and 11 defined level. This right angle is preferably in the area in which the first cut surface and the second surface intersect. Like it in the 1 can be seen, the two cut surfaces can also deviate from a flat surface. So it is in the 1 shown that the second cutting surface is angled and thus a wave-shaped second cutting edge 14th on the first radiator 7th results.

The first radiating body obtained in this way as a section of a three-axis ellipsoid 7th is spaced from a reflector 12 arranged. The reflector 12 forms a partial area of an antenna tower in the illustrated embodiment 15th . The antenna tower 15th consists preferably of 8 such partial areas, which are around a reflector axis 16 are arranged around symmetrically and closed.

While the second semiaxis 10 and the third semiaxis 11 in the first embodiment of an antenna 1 are the same length is the first semiaxis 9 longer. The first semi-axis 9 and the second semi-axis 10 run parallel to the reflector axis 16 . Regarding the reflector 12 is the first radiant body 7th oriented so that the intersection of the three semi-axes 9 , 10 , 11 who is the focus M. forms, between the first radiator 7th and the reflector 12 lies. The curvature of the first radiator 7th therefore points from the antenna tower 15th outward.

As already explained, the radiating elements are the antenna according to the invention 1 Dipole radiator. In addition to the first radiator 7th shows the dipole radiator 3 hence a second radiator 8th on. The second radiant body 8th corresponds in its geometry to the first radiator 7th . The second radiator 8th the basic ellipsoid shape on which it is based is therefore an ellipsoid with a first semiaxis 9 ' , a second semiaxis 10 ' as well as a third semi-axis 11 ' . In the illustrated embodiment of the 1 are the second and third semiaxes 10 ' , 11 ' of the second radiator 8th also of the same length and in particular the same length as the second and third semi-axes 10 , 11 of the first radiator 7th .

Also the first semi-axis 9 ' of the second radiator 8th is preferably the same length as the first semi-axis 9 of the first radiator 7th . In particular, the cut surfaces for defining the section of the ellipsoid also correspond. The first two semi-axes 9 , 9 ' and the surface normal of the reflector 12 define a first level. The first two semi-axes 9 , 9 ' can also enclose an angle other than 180 °. The reflector 12 consists of a flat surface, eight such flat surfaces to the antenna tower in the illustrated embodiment 15th are composed. In the illustrated embodiment, the first half-axes are 9 , 9 ' on a common straight line. Also the second and third semiaxes 10 , 10 ' and 11 , 11 ' the radiator 7th and 8th lie in pairs parallel to each other. The first radiant body 7th and the second radiator 8th are thus arranged symmetrically with respect to a second plane. The second level is on both the first level and the reflector 12 perpendicular.

As it has already been explained, are evenly around the antenna tower 15th made up of eight reflectors 12 consists, a total of eight dipole radiators arranged. The dipole radiators are each centered in front of a reflector 12 arranged and with respect to the reflector axis 16 axially identically positioned. Also the distance between the individual dipole radiators and their respective reflectors 12 is identical so that the midpoints M. , M ' of the first and second radiator 7th , 8th each on a circle centered on the antenna axis 16 are arranged.

From the antenna tower 15th a roof plate extends outward in the radial direction 17th . The roof plate 17th is with the antenna tower 15th connected and extends to a roof sheet edge 18th , which is preferably one with the geometry of the antenna tower 15th Has a corresponding shape. In the illustrated embodiment, the roof plate edge is therefore 18th a regular octagon. The roof plate 17th is arranged offset in the axial direction to the dipole radiators and has an axial distance from the dipole radiators d ₁ .

On the one from the roof plate 17th The side facing away from the dipole radiator is also a footplate 19th arranged. The footplate 19th also extends from the outer perimeter of the antenna tower 15th in the radial direction. The toe plate edge 20th points like the roof sheet edge 18th one with the cross section of the antenna tower 15th corresponding geometry and thus also corresponds in its course to a regular octagon. The footplate 19th is also arranged at a distance from the dipole radiators and points from the lower edge of the second radiator body 8th a second distance d ₂ , which is preferably the distance d ₁ corresponds.

In the illustrated preferred embodiment, both the roof plate 17th as well as the footplate 19th designed as flat surfaces. These flat surfaces extend in the radial direction the same distance from the antenna tower 15th so that there is a total of an antenna 1 results with high symmetry with respect to a plane of symmetry lying between the first and the second radiating body.

The individual dipole radiators are in the circumferential direction of the antenna tower 15th arranged at a distance from one another. In the distances thus formed between the individual dipole radiators, for. B. 4th , 5 , are both dividers 21st arranged. The dividers 21st extend in the illustrated embodiment from the roof panel 17th up to the toe board 19th . The dividing plates extend in the radial direction 21st from the antenna tower 15th outwards, but with the radial extension of the dividing plates 21st is smaller than the radial extension of the roof plate 17th and the toe board 19th . In the illustrated embodiment, there are dividers 21st arranged between all dipole radiators. However, it can also be advantageous to provide such a partition plate only between every second dipole radiator or to choose different radial or axial dimensions for different partition plates. In this way, the roundness of the radiation pattern can be influenced in particular.

In the 3 is a section through an antenna 1 from the 1 shown. The cutting plane lies parallel to the plane of symmetry of the antenna 1 in the area of the first distance d ₁ . In addition to the dipole radiators 2 to 6th , which is also shown in the perspective view of the 1 were already recognizable, the remaining dipole radiators are now 22nd to 24 to recognize. The eight dipole radiators 2 to 6th and 22nd to 24 are from the respective reflectors 12 arranged at a third distance d ₃ . The third semiaxis 11 extends in the direction of the surface normal of the reflector 12 . In the sectional view of the 3 it can be seen that the toe plate edge 20th corresponds to a regular octagon. The antenna is designed for a frequency range from 180 MHz to 600 MHz. There is an optimal compromise for an antenna tower 15th with a width of approx. 800 mm with an arrangement of eight dipole radiators. For other applications in which, for example, a different frequency band is to be covered, the number of dipole radiators can differ from this number. In particular, it is also possible to use an antenna tower with a circular cross-section as a reflector, in front of which the dipole radiators are then arranged.

In the 3 it can also be seen that the radial extension of the toe plate 19th is less than the maximum radial extension of the first and also of the second radiating element 7th or. 8th . The dividers 21st extend from the corners of the regular octagon in the radial direction. The radial extent is greater than the third distance d ₃ at which the first radiator body 7th and the second radiator 8th from the reflector 12 are arranged. At the same time is the radial extension of the dividing plates 21st smaller than the radial extension of the toe plate 19th .

In the 4th is a second, preferred embodiment of the antenna according to the invention 1 shown. The antenna corresponds in its essential structure 1' the Indian 1 shown antenna 1 . In contrast to this, however, are the radiators 7 ' and 8th' formed by sections of ellipsoids in which all three semi-axes are of different lengths. The first cut surface and the second cut surface, which define the section of the ellipsoid, are defined by the first and second semiaxes 9 , 10 of the first radiator 7 ' or the second and third semiaxes 10 , 11 '' of the first radiator 7 ' educated. This is the resulting radiant body 7 ' exactly a quarter of a complete ellipsoid. The first cut surface is parallel to the surface of the reflector 12 arranged. The second cut surface is perpendicular to the first cut surface and, like this, is a flat surface. The first radiant body 7 ' and the second radiator 8th' are oriented so that their respective shortest semiaxes 11 '' bwz. 11 '' 'perpendicular to the surface of the reflector 12 runs. The first radiant body 7 ' and the second radiator 8th' are thus in the direction of the reflector 12 too flattened compared to the embodiment of FIG 1 .

Another difference is that the dividing sheets do not extend over the full distance between the roof sheet 17th and footplate 19th . Rather, there are two sets of dividers 21 ' and 21 '' formed in which the first set of dividers 21 ' just a little way from the roof plate 17th towards the toe board 19th too extends.

The extent in the axial direction is preferably smaller than the first distance d ₁ the roof plate 17th in the axial direction of the Dipole emitters 2 to 6th and 22nd to 26th having. Corresponding to the first set of dividers 21 ' is starting from the footplate 19th a second set of dividers 21 '' educated. The second set of dividers 21 '' extends in the axial direction from the toe plate 19th in the direction of the roof plate 17th . The length of the axial extension corresponds to the length of the axial extension of the partition plates 21 '' of the second set of dividers. This particularly preferred arrangement of the flattened ellipsoids as dipole radiators 2 ' to 6 ' together with the dividers 21 ' and 21 '' which only cover part of the axial distance between the roof plate 17th and footplate 19th extend, have a particularly positive effect on the coupling of the individual dipole radiators. The result is particularly good roundness with a standing wave ratio (VSWR, voltage, standing, wave, ratio) that is uniform over a wide frequency range.

In the 5 Fig. 13 is a plan view of a section along a perpendicular to the antenna axis 16 lying cut surface in the area of the first distance d ₁ shown. The flattening of the radiating body 7 ' is easy to recognize in it. In addition, the 5 shown that connecting cables 25th from the respective surface of the reflector 12 in a direction perpendicular to the dipole radiators 2 ' to 6 ' and 22 ' to 24 ' extend.

In the 6th is once again an enlarged individual view of a dipole radiator 3 ' shown. The first semi-axis 9 of the first radiator 7 ' as well as the first semi-axis 9 ' of the second radiator 8th' run along a common straight line. The closed ends 26th and 27 of the first radiator 7 ' and the second jet body 8th' are oriented towards each other and at a distance d ₄ spaced from each other.

The second semiaxis 10 as well as those in the 6th unrecognizable third semiaxis 11 '' of the first radiator 7 ' define a plane that is the second cutting surface 28 forms. Place the second semiaxis accordingly 10 ' as well as the third semiaxis 11 '' 'of the second radiator 8th' the plane that the corresponding second intersection of the second radiant body 8th' forms.

The first cut surface 29 is in the 7th can be seen in the top view of the first radiator 7 ' is shown. The first cut surface 29 is thereby through the first semiaxis 9 as well as the second semi-axis 10 set. According to the particularly preferred embodiment, the ellipsoids are therefore defined by a first flat cut surface 29 and a second planar cutting surface 28 cut and so that section is determined that the geometry of the first and second radiator 7 ' or. 8th' forms. The first cut surface 29 and the second cut surface 28 are perpendicular to each other. Regarding the reflector 12 is the first cut surface 29 arranged in parallel. In the 8th Fig. 3 is once again a side view of the second embodiment of the antenna according to the invention 1' shown. In addition, in the first and second radiators 7 ' or. 8th' the entry points 30th shown. The entry points 30th are from the closed ends 26th or. 27 the first and second radiant bodies 7 ' or. 8th' spaced.

In the 8th it can also be clearly seen once again that the axial extent of the separating plates 21 ' and 21 '' of the first or second set of partition plates is smaller than the distance between the roof plate and the first radiator body 7 ' or the toe plate from the second radiators 8th' .

In the 9 is for an antenna according to the invention 1' the ripple of the standing wave ratio VSWR is given for a reference resistance of 100 ohms. It can be seen that the VSWR is less than 1.65 in the entire frequency band from 180 to 600 MHz. This course, which fluctuates only slightly, is created by the interaction of the sections of ellipsoids as a radiating body 7 ' , 8th' with the reflectors 12 as well as the roof and foot plates 17th , 19th and the dividers 21 ' , 21 '' reached. Adaptation by a matching network is not required.

At the same time, an antenna gain g is achieved, as shown in the diagram of FIG 10 is shown. For an angle of 90 ° to the antenna axis 16 the antenna gain g does not fall below a value of 2.0 dBi at any frequency over the entire frequency range. The use of the antenna according to the invention is therefore particularly suitable for applications in which a high antenna gain in the horizontal direction is required. Such applications make z. B. Antennas for shipping.

In the 11 a series of vertical charts is shown. Only the upper half of the symmetrical diagram is shown. The vertical diagrams show that in the vertical direction, i.e. on the antenna axis 16 practically no energy is radiated. The radiation takes place over the entire frequency range from approx. 180 MHz to 600 MHz, preferably at 90 ° to the antenna axis 16 standing direction.

12 shows the roundness of the antenna according to the invention 1' . It can be seen that an almost ideal roundness is achieved for the frequencies 300 MHz, 400 MHz and 500 MHz. The grouping of the eight individual dipoles can only be seen for 600 MHz.

The invention is not restricted to the exemplary embodiments shown. In particular, features of the individual exemplary embodiments can be combined with one another in any way.

Claims (19)

Antenna with at least one reflector (12) and at least one radiating element (2-6, 22-24, 2'-6 ', 22'-24'), which is arranged at a distance from the flat reflector (12) and which has at least one first Radiant body (7, 7 '), the geometry of which corresponds to a section of a three-axis ellipsoid, with all three semi-axes (9, 10, 11, 11 ") of different lengths and the shortest of the three semi-axes (11") being perpendicular to the Surface of the flat reflector (12) runs. Antenna after Claim 1 , characterized in that a center point (M) of the three-axis ellipsoid lies on the side of the radiating body (7, 7 ') facing the reflector (12). Antenna after Claim 1 or 2 , characterized in that the radiating body (7, 7 ') is oriented such that one of the three semi-axes (9, 10, 11, 11 ") is oriented approximately parallel to a surface of the reflector (12). Antenna after one of the Claims 1 to 3 , characterized in that the section forming the geometry of the jet body (7) is defined by a section of the triaxial ellipsoid with a first cutting surface (29) and a second cutting surface (28) arranged approximately perpendicular thereto. Antenna after one of the Claims 1 to 4th , characterized in that the first cut surface (29) runs parallel to a surface of the reflector (12). Antenna after one of the Claims 1 to 5 , characterized in that the radiating element (2 - 6, 22 - 24, 2 '- 6', 22 '- 24') is a dipole radiator which comprises a second radiating body (8, 8 '), the geometry of the first Radiant body (7, 7 ') and which is also arranged at a distance from the reflector (12). Antenna after Claim 6 , characterized in that a semiaxis (9) of the first radiator (7, 7 ') and a corresponding semiaxis (9') of the second radiator (8, 8 ') and a surface normal of the spaced reflector (12) in a common first plane lie. Antenna after Claim 7 , characterized in that the first and the second radiating body (7, 7 ', 8, 8') lie symmetrically to a second plane arranged perpendicular to the first plane and the surface of the reflector (12). Antenna after one of the Claims 6 to 8th , characterized in that the first and the second jet body (7, 7 ', 8, 8') are oriented towards one another, each with a closed end (26, 27). Antenna after one of the Claims 6 to 9 , characterized in that the reflector (12) has a closed geometry around an antenna axis (16) and several radiating elements (2-6, 22-24, 2'-6 ', 22'-24') around this closed geometry are arranged. Antenna after Claim 10 , characterized in that the plurality of radiation elements (2-6, 22-24, 2'-6 ', 22'-24') extend with their respective longitudinal axes in the direction of the antenna axis (16). Antenna after Claim 10 or 11 , characterized in that the axial position of the radiating elements (2-6, 22-24, 2'-6 ', 22'-24') with respect to the antenna axis (16) is identical. Antenna after one of the Claims 6 to 12 , characterized in that the radiating elements (2-6, 22-24, 2'-6 ', 22'-24') are arranged spaced along the circumference of the reflector (12) and in at least part of the spacing thus formed separating plate (21, 21 ', 21'') extending from the reflector (12) in the radial direction and along the antenna axis (16). Antenna after one of the Claims 6 to 13 , characterized in that a roof plate (17) is arranged at a distance in the axial direction from the beam element / s (2-6, 22-24, 2'-6 ', 22'-24') which extends from the reflector (12) extends outward in the radial direction. Antenna after Claim 14 , characterized in that, in addition to the roof plate (17), a toe plate (19) on the side of the radiation element (s) (2-6, 22-24, 2'-6 ', 22') facing away from the roof plate (17) - 24 ') and is arranged at a distance from these in the axial direction and the toe plate (19) extends outward from the reflector (12) in the radial direction. Antenna after Claim 15 , characterized in that the roof plate (17) and the foot plate (19) have an identical geometry. Antenna after Claim 15 or 16 , characterized in that the roof and / or footplate (17, 19) are flat and the surface normal this plane coincides with the antenna axis (16). Antenna after one of the Claims 15 to 17th , characterized in that the radiating elements (2-6, 22-24, 2'-6 ', 22'-24') are arranged spaced along the circumference of the reflector (12) and in at least part of the spacing thus formed is arranged from the reflector (12) in the radial direction and along the antenna axis (16) extending partition plate (21, 21 ', 21 ") and that at least some of the partition plates (21', 21") extend over only one Part of the axial distance between the roof plate (17) and toe plate (19) extend. Antenna after one of the Claims 15 to 18th , characterized in that at least some of the partition plates (21) extend in the axial direction from the roof plate (17) to the base plate (19).

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