DE202018002096U1 - Controlled radiation pattern antenna - Google Patents

Abstract

Controlled Radiation Pattern Antenna with,
an electrically conductive base plate (12),
four L1 / E1 dielectric resonator antennas (14a-14d) arranged on the base plate (12) and operating in the L1 / E1 band,
a central dielectric resonator antenna (16) which is arranged centrally on the base plate (12) in the radial direction between the four L1 / E1 dielectric resonator antennas (14a - 14d) and their operation in one of the bands L2 and / or E6 he follows.

Description

The invention relates to a controlled radiation pattern antenna.

Such antennas are known in the art for use in GNSS navigation. They are able to suppress interference from unwanted or intentional sources of interference (such as attackers).

The essential elements of a CRPA antenna are an antenna array, a frontend unit and a digital signal processor. The antenna arrangement has a plurality of individual antennas, from each of which GNSS signals can be received. With a suitable combination of the input signals, directions from which signals can be received worse can be placed in the direction of interfering signals, so that they are suppressed. The front-end unit converts the RF signals present at the output of the antennas into filtered intermediate frequency (IF) signals which are fed to the digital signal processor. Here, interference suppression algorithms are used by analyzing the received signals for suppression of interferences. For example, suitable weighting vectors can be calculated at the antenna outputs so that the interfering signals can be suppressed.

CRPA antenna arrays known in the art are known, for example, the Novatel GAJT-710ML antenna system and the Raytheon's Landshield system.

Antennas known from the prior art usually have large dimensions, so that they can not be integrated into mobile devices. Furthermore, prior art antennas have interference cancellation in both the GPS L1 and L2 bands. This increases the complexity of the antenna since two non-adjacent bands must be accommodated in the same antenna. When the available size for the antenna is limited, the performance of each band often suffers. In order to achieve good performance in both bands, the antennas must be increased, but this negatively affects their usability in different devices. In addition, the suppression in both the L1 and L2 bands increases the number of channels (which is the number of antennas multiplied by the number of bands where interference is to be suppressed). This increases the computational complexity in the signal processing. If other bands such as L5 / E5a / E6 need to be considered, interference suppression can not be ensured due to the large increase in complexity and associated costs.

The object of the invention is to provide a Controlled Radiation Pattern antenna, which has compact dimensions and at the same time provides the necessary bandwidths for all GNSS signals in the L band.

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

The controlled radiation pattern antenna according to the invention has an electrically conductive base plate whose edge is preferably surrounded by a ring of RF-absorbing material. For example, in all embodiments of the invention, an RF-absorbing material may have dielectric losses greater than 0.01 (tangent delta). Furthermore, four L1 / E1 dielectric resonator antennas are provided, which are arranged on the base plate and their operation takes place in the L1 / E1 band. Furthermore, a central dielectric resonator antenna is provided, which is arranged centrally on the base plate in the radial direction between the four L1 / E1 dielectric resonator antennas and whose operation takes place in one of the bands L2 and / or E6. The four antennas mentioned can additionally receive signals in the Glonass G1 band.

It is preferable that the four L1 / E1 dielectric resonator antennas are arranged in the form of a square relative to each other, each of the four antennas forming one corner of the square. At the very center of this square is preferably the central DRA antenna.

The invention takes advantage of the fact that CRPA functionality is absolutely necessary only in the L1 / E1 bands, while signal reception at lower bands (even with a single antenna without integrated interference cancellation) can be used to increase availability and provide alternative signals in case of strong interference. Further, in the lower bands (L2 / E5a), interference resistance is already achieved by the encryption of the signals for military purposes, so that antennas in these bands are less vulnerable.

The antenna according to the invention makes it possible to receive all the signals in the GNSS bands, including the wideband signals, for example E1, E5 in the Galileo system. Furthermore, interference suppression can take place for all L1 / E1 signals.

The front-end and the digital signal processing can be simplified according to the invention, since it is not necessary to perform an interference suppression in all bands.

It is preferred that all the dielectric resonator antennas are cylindrical and in particular have a circular cylindrical shape. You can still have a relative electrical permettivity of over 20 exhibit.

Furthermore, it is preferable for the dielectric resonator antennas to comprise a glass-ceramic material. This allows a very compact design of the antennas. It is further preferred that the side remote from the base plate side of the dielectric resonator antennas is covered with a particular circular copper plate. As a result, the miniaturization can be further improved. Furthermore, this can be the fine tuning of the antennas can be improved.

In order to improve the mechanical stability and to protect against external influences, it is furthermore possible to provide a cover made of solid material which, in the region of the dielectric resonator antennas, has in particular cylindrical recesses for receiving the respective dielectric resonator antenna. This cover is not hollow, but consists of solid material and has only said recesses for receiving the dielekrischen resonator antennas, so that an improved mechanical stability can be achieved. The cover can be made of Plexiglas or synthetic resin. Furthermore, it may be made of a plastic material, optionally by a 3D printer. Furthermore, the use of a low-loss dielectric material is preferred.

It is further preferred to provide four mounting screws for mounting the CRPA antenna to an underlying surface. The four fastening screws can each be surrounded in the radial direction by a ring of RF-absorbing material.

It is preferred that the four fastening screws are arranged in the form of a square relative to each other, wherein each fastening screw is arranged at a corner of the square. The square preferably has a side length of 4.8 cm. This corresponds to the individual antennas currently in use, such as the GPS S67-1575 antenna. The retrofitting of the antenna according to the invention in existing platforms is thus simplified. The fastening screws may comprise a metallic material which has been taken into account in the calculation of the electromagnetic properties of the antenna. The influence of the electromagnetic properties by the metallic material of the screws can be reduced by the RF-absorbing material surrounding the screws.

• 1a - 1c ein Beispiel für eine Antenne,
• 2a - 2c eine Ausführungsform der erfindungsgemäßen Antenne,
• 3a - 3c ein Beispiel für eine weitere Antenne.

In the following, preferred embodiments of the invention will be explained with reference to figures. Show it:

• 1a - 1c an example of an antenna,
• 2a - 2c an embodiment of the antenna according to the invention,
• 3a - 3c an example of another antenna.

In the example according to the 1a - 1c the CRPA antenna has an electrically conductive base plate 12 on, the edge of a ring 15 surrounded by RF-absorbing material. The electric base plate 12 is preferably circular. The antenna 10 has exactly four L1 / E1 dielectric resonator antennas 14a - 14d on that on the base plate 12 are arranged. The operation of these antennas takes place in the L1 / E1 band. This means that the dimensions and material of these antennas are chosen such that their resonant frequency lies in said bands.

Each of these antennas is at theirs from the baseplate 12 opposite side with a circular copper plate 18a - 18d covered.

In the middle of the electrically conductive base plate 12 is a central dielectric resonator antenna 16 whose operation takes place in one of the bands E5 / L5 / L2 and / or E6, preferably in L2 / E6.

Each of the dielectric resonator antennas 14a - 14d . 16 is powered by two electrical leads connected to electrical components located below the metallic base plate 12 are arranged. Each of these electrical supply lines 19a - 19d excites a linear component of the electromagnetic field. The signals of the two feed lines are then in the electrical circuit below the base plate 12 combined by a broadband 90 ° hybrid circuit. RHCP and LHCP polarized output signals are generated from the two linear components. These are then routed to the frontend and the digital signal processor. This is done by RF connectors, which may preferably be MMBX connectors.

It is possible, in all embodiments of the invention, to pass only the RHCP output signal while blocking the LHCP output signal. This can be done for example by a 50 ohm resistor.

As in 1c visible, the antenna points 10 a cover 24 made of solid material. This has circular cylindrical recesses for each DRA antenna 14a - 14d . 16 on, so that the mechanical stability of the antenna 10 can be increased.

The antenna 10 may have a diameter of about 150 mm and an axial height of less than 20 mm. The diameter for the four L1 / E1 dielectric resonator antennas 14a - 14d may be 15-25 mm in all embodiments of the invention. The diameter for the central antenna 16 may be 25-30 mm in all embodiments of the invention. The height of all antennas can be 5 - 20 mm. Furthermore, the distance of the four dielectric L1 / E1 antennas 14a - 14d from the center of the base plate 12 15-30 mm.

Furthermore, the central DRA antenna 16 operated in the L2 / E6 band.

The second embodiment of the antenna according to the invention according to the 2a - 2c is basically similar, with the four L1 / E1 DRA antennas 14a - 14d have a smaller distance from the central antenna.

This distance can be 15 - 30 mm. Furthermore, the height of all antennas can be 5 - 20 mm.

In the embodiment of the invention according to the 2a - 2c are the screws 22a - 22d in the radial direction outside of the four L1 / E1 DRA antennas 14a - 14d that is, the center of each screw is located radially outward of the center of the respective DRA antenna 14a - 14d , Accordingly, the fastening screws 22a - 22d no ring of RF-absorbent material, as was the case with the first example. In this first example are the mounting screws 22a - 22d in contrast, in the radial direction within the four dielectric resonator antennas 14a - 14d arranged.

The embodiment of the antenna 10 according to 2a - 2c may have a diameter of about 90 millimeters and an axial height of less than 20 millimeters.

The embodiment according to 2a - 2c may have all the features described in connection with the first example.

A third example of an antenna 10 is in 3a - 3c shown. Again, the mounting screws 22a - 22d in the radial direction outside the DRA antennas 14a - 14d arranged.

The cover 24 (S. 3c) is curved and thus has an improved mechanical stability. The central antenna 16 In the third example, the band is operated in L5 / E5A and can optionally also be operated in the L2 / E6 band.

The third example of the antenna may have a diameter of about 90 mm and a height of less than 30 mm.

In all embodiments of the antenna according to the invention, it is possible to provide more than four L1 / E1 dielectric resonator antennas. For example, an antenna for the Glonass G1 band can additionally be used.

In all embodiments / examples of the antennas according to the invention, the bands mentioned can cover the following frequencies:
L1 / E1: 1559-1591 MHz; L5 / E5a: 1164-1189MHz; L2: 1215-1239 MHz; E6: 1260-1300 MHz, Glonass G1 band: 1593-1610 MHz

Claims (8)

Controlled Radiation Pattern Antenna with, an electrically conductive base plate (12), four L1 / E1 dielectric resonator antennas (14a-14d) arranged on the base plate (12) and operating in the L1 / E1 band, a central dielectric resonator antenna (16) which is arranged centrally on the base plate (12) in the radial direction between the four L1 / E1 dielectric resonator antennas (14a - 14d) and their operation in one of the bands L2 and / or E6 he follows. Controlled radiation pattern antenna after Claim 1 wherein the spacing of the four L1 / E1 dielectric resonator antennas (14a-14d) from the center of the base plate (12) is 15-30mm. Controlled radiation pattern antenna after Claim 1 to 2 , characterized in that all the dielectric resonator antennas (14a - 14d, 16) are cylindrical and have a relative electrical permittivity of over 20. Controlled radiation pattern antenna after Claim 1 to 3 , characterized in that the dielectric resonator antennas (14a - 14d, 16) comprise a glass-ceramic material. Controlled radiation pattern antenna after Claim 1 to 4 , characterized in that the side facing away from the base plate (12) of the dielectric resonator antennas (14a - 14d, 16) with a particular circular copper plate (18a - d, 20) is covered. Controlled radiation pattern antenna after Claim 1 to 5 , characterized by a cover (24) made of solid material, which in the region of the dielectric resonator antennas (14a - 14d, 16) in particular cylindrical recesses for receiving the dielectric resonator antennas (14a - 14d, 16). Controlled radiation pattern antenna after Claim 1 to 6 characterized by four mounting screws (22a-22d) for attaching the CRPA antenna (10) to an underlying surface. Controlled radiation pattern antenna after Claim 1 to 7 , characterized in that the edge of the electrically conductive base plate (12) is surrounded by a ring of RF-absorbing material.

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