EP1894269A1 - Antenna assembly - Google Patents

Abstract

The assembly has a mast (1) and antenna structures (2) that are mounted on the mast. The mast is constructed from truncated cone shaped structures (3) and a surface normal of the antenna structures forms an angle with a normal (S a) in the mast axis z of between 5 and 35 degrees. The cone-shaped structures are alternatively connected with one another at the base surface and the cover surface.

Description

Antenna arrangement

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

An arrangement of a DF antenna is known from [1]. The antenna comprises a mast section which serves as a UHF antenna and a further mast section which serves as a VHF antenna.

Such an antenna arrangement is often used in DF antenna systems, such as those used on naval ships. A known requirement for such ships is known to be the invisibility of the respective ship to the opposing radar. Since the DF antennas are always located at the top of a ship's mast, they first protrude above the horizon and can thus be easily detected. The decisive factor for the detection of an object using radar is the respective monostatic radar backscatter cross section of the respective object. The application results in a threat sector to be optimized which corresponds to the angular range of the possible incident radar radiation from the opposing radar.

The object of the invention is to provide a generic antenna arrangement with an optimized, low monostatic radar backscatter cross section for the threat sector.

This object is achieved by the antenna arrangement according to the features of claim 1. Advantageous embodiments of the invention are the subject of subclaims.

The antenna arrangement according to the invention comprises a mast and antenna elements arranged on the mast, the mast being constructed from a plurality of frustoconical elements and a surface normal of the antenna elements forming an angle lαl of between 5 ° and 35 ° with the perpendicular to the mast axis z. The mast axis z coincides with the symmetrical axis of each frustoconical element.

These measures make it possible to reduce the monostatic radar backscatter (RCS) of the antenna arrangement in the threat sector by more than 10dB. This significantly reduces the distance an enemy radar can detect the ship. Monostatic here means that the direction of incidence and the direction of exit of the radar radiation are the same, or in other words the radar transmission antenna and the radar reception antenna of the opposing radar have the same position. This is the case with most radar systems (e.g. a ship radar)

The individual frustoconical elements of the mast are advantageously connected to one another alternately on the base surfaces and on the ceiling surfaces. The surface areas of the base and ceiling surfaces lying on top of one another are expediently the same in each case. In the following, the base area is the area perpendicular to the symmetrical axis of the truncated cone, which results from the largest diameter of the truncated cone. The ceiling surface accordingly designates that surface of the truncated cone which results from the smallest diameter of the truncated cone.

The mast therefore essentially consists of several double truncated cones. The transitions between the individual truncated cones are expediently carried out homogeneously, i.e. no flanges are used. In particular, in a preferred embodiment of the invention, the surface normals on the lateral surfaces of two adjacent, frustoconical mast elements connected to one another on the ceiling surfaces have an angle of less than 90 °. This prevents the two lateral surfaces from serving as an ideal reflector.

The mast is expediently mounted on a base plate. Here, the mast is advantageously applied to the base plate in such a way that a normal is on the top the base plate forms an obtuse angle with a normal to the outer surface of the first frustoconical element applied to the base plate. This ensures that the mast stands securely.

The invention and further advantageous embodiments are explained in more detail below with reference to figures. Show it:

1 schematically shows a mast section of an antenna arrangement according to the prior art,

2 schematically shows a mast section of an exemplary antenna arrangement according to the invention,

3 shows, for a mast section of an antenna arrangement according to FIG. 1, an exemplary course of the monostatic radar backscatter as a function of the angle Wink and the radar frequency f,

4 for a mast section of an antenna arrangement according to the invention in accordance with FIG. 2 shows an exemplary course of the monostatic radar backscatter as a function of the angle Θ and the radar frequency f,

5 shows an exemplary representation of a mast optimized with regard to monostatic radar backscattering,

6 shows the course of the monostatic radar backscattering for a cylindrical mast of the exemplary length of 1 m and an exemplary diameter of 125 mm as a function of the angle Θ and the radar frequency f.

7 shows the course of the monostatic radar backscattering for a mast of an antenna arrangement according to the invention of the exemplary length of 1 m and an exemplary maximum diameter of 125 mm depending on the angle Θ and the radar frequency f. 8 shows an exemplary antenna arrangement according to the invention with a mast section for a UHF antenna and a further section for a VHF antenna.

Fig. 1 shows a section of a known antenna arrangement, such as e.g. is known from [1]. The arrangement is characterized by an essentially cylindrical mast 1, on which radially symmetrical antenna elements 2 are arranged. The antenna elements are expediently designed as dipole elements. The mounting (not shown) of the antenna elements 2 on the mast takes place via known measures, e.g. non-conductive connections.

2a schematically shows an exemplary section of an antenna arrangement according to the invention. The section comprises two truncated cones 3 which are connected to one another at their base surfaces. The two truncated cones thus form a kind of double truncated cone.

The truncated cones 3 expediently have a concentric through hole (not shown) with a diameter smaller than the smallest diameter of a top surface of a truncated cone. This hole is used for the passage of measuring cables etc. (not shown). The truncated cones 3 are connected by means of screw connections (not shown) made inside the truncated cones 3. These screw connections are expediently accessible through the hole for cable routing.

2a shows a plurality of antenna elements 2, which are advantageously arranged on a circular line, the circle lying in a plane perpendicular to the mast axis with a diameter larger than the maximum diameter of a frustoconical element. The antenna elements 2 are expediently arranged uniformly on the circular line, the antenna elements 2 being positioned on the circular line at a fixed angle to one another. In an advantageous embodiment of the invention, the antenna elements 2 are aligned parallel to the radially spaced lateral surface 4 of the frustoconical element 3. Furthermore, the antenna elements 2 are aligned as dipoles D. The center of gravity S of a dipole D is expediently in the plane of

Base areas of the two truncated cones 3 connected to one another. However, it is also possible for the center of gravity S of a dipole D to be in the plane of the ceiling areas.

In FIG. 2a, the angle zusätzlich is additionally defined as the mathematical angle between the direction a of the incident and backscattered radar radiation and the mast axis z. This results in an elevation angle (not shown) of 90 ° -Θ. 2b shows the definition of the angle Θ and the definition of the azimuth angle Φ.

3 and 4 as well as FIGS. 6 and 7 assume that radar radiation is incident on the respective body along the direction a (FIG. 2a) to the mast axis z. The angle Θ thus indicates the angle of incidence and backscatter of the incident radar radiation in relation to the mast axis z. The azimuth angle Φ is 0 ° in all diagrams for the sake of simplicity.

3 shows, for a known antenna arrangement according to FIG. 1, an exemplary course of the monostatic radar backscatter as a function of the angle des and the radar frequency f.

In contrast, FIG. 4 shows an exemplary course of the monostatic radar backscatter as a function of the angle Θ and the radar frequency f for an antenna arrangement according to FIG. 2a according to the invention. It is clear from the comparison of FIG. 3 with FIG. 4 that the monostatic radar backscatter for the antenna arrangement according to the invention has been significantly reduced at the respective radar frequencies in the angular range near the vertical of the mast. For example, the monostatic radar backscattering of a mast section of a known antenna arrangement at 2.5 GHz, at an angle Θ of 87.5 °, approximately -5 dB (cf. FIG. 3). With a mast of an antenna arrangement according to the invention, the monostatic radar backscattering at 2.5 GHz at an angle Θ of 87.5 ° is approximately -22.5 dB.

FIG. 7 shows the course of the monostatic radar backscattering for a mast of an antenna arrangement according to the invention, as shown in FIG. 5, with an exemplary length L of 1 m and an exemplary maximum diameter DM of 125 mm depending on the angle Θ and Radar frequency f shown. 6 shows the course of the monostatic radar backscattering of a cylindrical mast with an exemplary length of 1 m and an exemplary diameter of 125 mm depending on the angle in and the radar frequency f. It is clear from the comparison of FIG. 6 with FIG. 7 that the monostatic radar backscattering for a mast of the antenna arrangement according to the invention was significantly reduced at the respective radar frequencies. For example, the monostatic radar backscattering of a mast of a known antenna arrangement at 2.5 GHz is approximately -13 dB at an elevation angle of 87.5 ° (cf. FIG. 3). In a mast of an antenna arrangement according to the invention, the monostatic radar backscattering at 2.5 GHz at an angle Θ of 87.5 ° is approximately -22.5 dB.

With the antenna arrangement according to the invention it is thus possible to reduce the monostatic backscatter in the azimuth range 0 ° Φ Φ <360 ° and in the range 60 ° <Θ <90 °, the latter corresponding to an elevation range of 0 ° to 30 °.

8 finally shows a further exemplary antenna arrangement according to the invention. This antenna arrangement comprises an arrangement for a UHF antenna in an upper section A of the mast 1 and an arrangement for a VHF antenna in a lower section B. In this case, the antenna elements 2 are in several Planes arranged perpendicular to the mast axis z, which makes it possible to operate individual sections A, B of the antenna arrangement, each with different frequency ranges. Of course, it is possible that the antenna arrangement is divided into several sections, each section being assigned to a different frequency range from the UHF and / or VHF range.

To reduce the radar backscatter, the length of the surface line s1, s2 of a truncated cone-shaped element 3 is advantageously greater than the wavelength of the radar wavelength incident on the antenna arrangement. Furthermore, the circumference of the frustoconical element 3 with the largest diameter DM is larger than the wavelength of the radar wavelength incident on the antenna arrangement. It is possible that the length of the surface line s2 of a frustoconical element 3 differs from the length of the surface line s1 of another frustoconical element 3.

The antenna elements are advantageously connected to the mast 1 via non-conductive brackets H. The antenna elements 2 expediently have a flat surface.

In the upper section A for the UHF antenna, the antenna elements 2 are expediently aligned parallel to the lateral surface 4 of the frustoconical element 3. In this case, the mast 1, which is optimized with regard to radar backscattering, serves as a reflector for the antenna elements 2.

In the lower section B for the VHF antenna, the antenna elements 2 are expediently not aligned parallel to the lateral surface 4 of the frustoconical element 3.

The antenna elements 2 can expediently be arranged as five-element interferometer antennas. The antenna elements 2 can also advantageously be made of be made of a circuit board material, in particular components such as resistors, capacitors or coils being integrated into the antenna elements 2 (not shown). These components serve as damping elements and influence the antenna properties. This can, for example, increase the bandwidth of the antenna. Furthermore, the radiation coupling between the individual antenna elements 2 can thereby be reduced. Of course, different antenna elements 2 can be used in the upper section A than in the lower section B.

According to the invention, the surface normal S_E of the antenna elements 2 forms an angle | α | with the perpendicular S_A on the mast axis z between 5 ° and 35 °.

The individual frustoconical elements 3 of the mast 1 are advantageously connected to one another alternately on the base surfaces and on the ceiling surfaces, and the base and ceiling surfaces lying on top of one another are in each case identical. The mast 1 thus essentially consists of several double truncated cones. The transitions between the individual truncated cones are expediently carried out homogeneously, i.e. no flanges are used. In particular, in a preferred embodiment of the invention, the surface normals L1, L2 on the lateral surfaces 4 of two adjacent frustoconical mast elements 3 have an angle β less than 90 °. This prevents the two adjacent lateral surfaces 4 from serving as an ideal reflector.

The mast 1 is expediently applied to a base plate P. Here, the mast 1 is advantageously applied to the base plate P such that a normal L3 on the top of the base plate P with a normal L4 on the lateral surface 4 of the first frustoconical element 3 applied to the base plate P forms an obtuse angle γ. This ensures that the mast 1 stands securely. The proposed antenna arrangement can be used with transmitting and / or receiving antennas and with direction finding antennas. Depending on the application, the frequency range in which the antenna arrangement can be operated lies in the HF range between 1.0 MHz and 30 MHz, in the VHF range between 20 MHz and 200 MHz, in the UHF range between 200 MHz and 3000 MHz. Of course, it is possible that with appropriate dimensioning of the individual components of the antenna, for example the dimensions of the individual truncated cones, the antenna arrangement can also be operated at lower or higher frequencies.

literature

[1] www.mrcm.net/media/pdf/products/antennas/mra1282.pdf

Claims

Claims

1. Antenna arrangement comprising a mast (1) and antenna elements (2) arranged on the mast (1), characterized in that the mast (1) is constructed from a plurality of frustoconical elements (3) and has a surface normal S_E of the antenna elements (2) the perpendicular S_A to the mast axis z an angle | α | form between 5 ° and 35 °.

2. Antenna arrangement according to claim 1, wherein the individual frustoconical elements (3) of the mast (1) are alternately connected to one another on the base surfaces and on the ceiling surfaces, and the base and ceiling surfaces lying on top of one another are each the same.

3. Antenna arrangement according to claim 2, wherein the angle β between the surface normals (L1, L2) on the lateral surfaces (4) of two adjacent frustoconical elements (3) is less than 90 °.

4. Antenna arrangement according to one of the preceding claims, wherein the mast (1) on a base plate (P) is applied such that a normal (L3) on the top of the base plate (P) with a normal (L4) on the outer surface (4th ) of the first frustoconical element (3) applied to the base plate (P) forms an obtuse angle γ.

5. Antenna arrangement according to one of the preceding claims, wherein to reduce the radar reflecting surface of the antenna arrangement, the length s1, s2 of the surface line of a truncated cone-shaped element (3) is greater than the wavelength of the radar wavelength incident on the antenna arrangement.

6. Antenna arrangement according to one of the preceding claims, wherein to reduce the radar reflecting surface of the antenna arrangement, the maximum circumference of a truncated cone-shaped element (3) is greater than the wavelength of the radar wavelength incident on the antenna arrangement.

7. Antenna arrangement according to one of the preceding claims, wherein the length s1 of the surface line of a frustoconical element (3) differs from the length s2 of the surface line of another frustoconical element (3).

8. Antenna arrangement according to one of the preceding claims, wherein a plurality of antenna elements (2) are arranged on a circular line, the circle lying in a plane perpendicular to the mast axis z with a diameter larger than the maximum diameter of a frustoconical element, such that the antenna elements ( 2) are arranged uniformly on the circular line, the antenna radiating elements (2) being positioned on the circular line at a fixed angle to one another.

9. Antenna arrangement according to claim 8, wherein the antenna elements (2) are aligned parallel to the radially spaced lateral surface (4) of the frustoconical element (3),

10. Antenna arrangement according to claim 8 or 9, wherein the antenna elements (2) are arranged in several planes perpendicular to the mast axis z.

11. Antenna arrangement according to one of the preceding claims, wherein the antenna elements (2) are designed as dipoles.

12. Antenna arrangement according to one of the preceding claims, wherein the antenna elements (2) with the mast (1) via non-conductive holders (H) are connected.

13. Antenna arrangement according to one of the preceding claims, wherein the antenna elements (2) have a flat surface.

14. Antenna arrangement according to one of the preceding claims, wherein the antenna elements (2) are made of printed circuit board material.

15. Antenna arrangement according to claim 14, wherein in the antenna elements (2) components, in particular resistors, capacitors or coils are integrated.