DE2855623A1 - Phase controlled wide range three-dimensional radar system - has both discrete radiators connected to separate branching networks and regulated in groups by phase-shifters - Google Patents

Abstract

The system generates independent 'diagrams' using electron beam tuning. Various drive-modes are provided for the three-dimensional radar system i.e. multiple-beam drive, frequency and polarisation operational modes. Both the discrete radiators are each connected to one of two separate branching networks. The phase-shifters are arranged at their lines in such a way that the phase positions (relationships) of the discrete radiator(s) of the system for generating a prescribed radiation (beam) characteristic can be regulated in gps. Both the branching networks with the discrete radiators can be driven independently as well as in coupled relationship.

Description

"Wide range 5D radar"

The invention relates to a phased 3-D radar antenna system to generate one or more independent diagrams by means of electronically controlled Phase shifter.

The use of electronically controllable phase shifter enables that Change of direction of an antenna beam within a very short time and thus makes the use of a 3D radar system makes sense. The time to scan a solid angle range can be shortened by using several beams.

Such an arrangement is e.g. B. known from DE-OS 25 41 316, according to in an antenna system with correspondingly spacious measured distances between the individual Elements a second antenna system with the same structure is nested. Each A suitable phase shifter and the phase shifter are arranged in the antenna element an antenna system become jointly independent of the second System controlled. The polarization directions of the two antenna systems radiated waves are perpendicular to each other. However, this arrangement allows only operates with linearly polarized radiation and is also through use two antenna systems with a phase shifter for each individual antenna element quite elaborate.

The object of the present invention is to provide the various for a 3D radar advantageous operating options, such as B. multi-beam operation, frequency diversity, Polarization diversity to be combined in one system with as little effort as possible.

The invention enables the construction of a 3D radar system that has a Has a multitude of advantageous uses and modes of operation characterized by a space-saving and economically favorable structure.

The antenna system according to the invention is composed of a large number of radiation elements, which are planar in a matrix with superimposed horizontal rows are arranged. Each radiation element consists of two polarization-decoupled ones Individual radiators, each through one of two separate branching networks with a radiation source are connected. The individual radiators mentioned here and below form a structural and functional unit in the radiation element, but can can still be operated independently of one another. Such or similar radiation elements are z. B. from DE-OS 20 54 169 already known.

In the case of the radiation elements used in the antenna system according to the invention can be linear or independent of each other via both individual radiators circularly polarized radiation are emitted.

On the branches of the branch networks are electronic Controllable phase shifter arranged so that the phase positions of the individual radiators of the system in groups depending on the desired radiation characteristics can be regulated. The two branching networks are usefully the same built up.

Essential for the invention are in addition to the use of the special Radiating elements the possibility of the two branching networks (with the respective connected single radiators) to be able to operate independently of each other, as well as to couple both networks and to operate them together and the special one Construction of the branching networks, which is particularly space-saving and economical has a beneficial effect.

The one fed into the feed line 1 of a branching network Radiated power is generated through the supply lines of a vertical branching system 3 distributed over different horizontal rows of radiators. On each of these branches a phase shifter 4 is attached. After this phase shifter, the radiation power in each of these horizontal planes by a horizontal branching system 5 distributed over the individual radiators. Depending on whether the individual radiators are such Row of radiators in phase or in individual groups with different phases can be operated on the branch lines of the horizontal branching system phase shifter 6 can still be attached at any point that can be expediently selected.

In principle, there is also an arrangement in which the radiation fed in first in a horizontal branching system and then in individual vertical ones Branching systems is divided, usable. For the application of the 3D radar However, the essential thing is the elevational beam swivel, which is carried out via the phase shifter 4 of the vertical branching system takes place. For building with a horizontal and several vertical branching systems this would result in the vertical Branching systems each A phase shifter is assigned to individual radiators had to be, which would increase the effort quite considerably.

The completely independent control and supply of the two networks allows the space to be scanned with two beams, and thus the time necessary for space scanning. Of course, this also applies analogously to the case that a radiator system has a diagram with several lobes.

In a simple embodiment, they are from the individual radiators radiated waves linearly polarized, namely for all radiators of a branching network in the same direction. The polarization direction of the radiators of the other branch network in this case is advantageously perpendicular to that of the one branching network. In the case of completely separate branching networks with a separate feed, you have the possibility of the room with two independent beams that are also independent of each other can be swiveled to scan.

The emission of circularly polarized waves is also advantageous through the individual radiators. The direction of rotation of the circular polarization is for the Select different emitters of the different networks.

The use of circularly polarized radiation is beneficial for the suppression of disturbances such as B. caused by rain.

With separate supply of the two branching networks, as above described, with two independent transmitters you get two beams with orthogonal Polarization that can be handled independently.

This affects both the beam swivel and the frequency of the radiated waves.

The two transmitters can therefore also be operated at different frequencies will.

This also results in the possibility of swiveling the beam Frequency change with unchanged setting of the phase shifter.

With common supply and the same phase control of the two branching networks there remains only one common beam to scan the space. However, this Operating mode any polarization can be set.

When linearly polarized radiation is emitted by the individual radiators result z. B. the following possibilities: The two networks become in phase fed, so can by varying the power distribution, z. B. by a power divider with a variable division ratio or by damping one of the two feed lines, and possibly by a phase element 2 with 1800 phase rotation in one of the feed lines due to the superimposition of the radiation emitted by the individual radiators with one another perpendicular polarizations a beam of any polarization direction can be generated. If you take a 90 0 phase element instead of the 1800 phase element, you get a more uniform Feeding of the two networks of circularly polarized radiation, their direction of rotation depends on it depends in which of the two feed lines the 900 phase shift takes place. If the power distribution is also varied, the result is elliptically polarized Radiation with the main axes of the ellipse parallel to the polarization directions of the Single emitter.

When emitting right circularly and left circularly polarized radiation the two individual radiators result in a complete one in a particularly simple manner Freedom in the choice of polarization.

Pure circularly polarized radiation is obtained by using only one which feeds both networks. When feeding both networks with coherent signals the same amplitude results in linearly polarized radiation and its polarization direction by a phase-shifting element 2 in the feed line to one of the networks can be set at will.

If you also take the possibility of varying the power distribution to the two networks, any type of polarization (any elliptical polarization included).

Switching means are in the feed devices 7 for the two networks provided that the change of operating mode - both networks independently or both Coupled networks - enable.

With the structure of the branching networks described, this results also in a simple way the possibility to carry out the in the specialist literature As a "back looking" process called, in which the beam in two different Azimuth directions can be set: With the 3D radar systems, the scanning takes place of space in general such that the sharply focused beam is in elevation is pivoted electronically while rotating the entire antenna by one vertical axis of the azimuth angle is continuously changed. Is now at the When scanning at the target, it may be desirable for a variety of reasons to pass over this area again without the time for the entire rotation the antenna. For this purpose, the usual scanning is carried out with the Beam in the azimuthal setting in the direction of rotation of the antenna.

When a target is detected, the system switches to the other setting of the beam, which now sweeps over the same angular range again.

The horizontal rows of the Arrays divided into individual radiator groups, as described, and these groups are linearly progressive in phase shifts along a series from group to group fed. You need two different ones for the two jet settings Phase progressions that can be switched between as required, and which are advantageously antisymmetric to one another.

This can be realized by setting the requirements accordingly Phase shifter in the supply lines to the individual radiator groups or through a series feed to be measured accordingly for the individual groups. The phase relationships the radiator elements within a group are not changed as a result.

Claims (11)

Claims 1.) Phase-controlled 3D radar antenna system for Generation of one or more independent diagrams with electronic beam swivel by means of electronically controlled phase shifters with a large number of radiation elements, which are arranged over a large area in a matrix with horizontal rows lying one above the other and each of which is made up of two individual radiators, characterized by that in each radiating element the two individual radiators are connected to one of two separate ones Branch networks are connected, and that on the branch lines the branching networks phase shifters are arranged so that the phase positions the individual radiators of the system to generate a certain radiation pattern can be regulated in groups, and that the two branching networks with the connected individual radiators operated both independently and coupled can be. 2. Antenna system according to claim 1, characterized by a vertical one Branching system that distributes the injected radiation to individual ones arranged one above the other Radiators distributed in rows, and by phase shifters, one of which on each Branch line to such a row of radiators is arranged, and to the elevational Beam influencing are provided. 3. Antenna system according to claim 2, characterized by a horizontal one Branch system to each row of radiators, which is that of the vertical branch system Radiation power distributed over the various rows of radiators to the individual ones Radiators distributed in series, and through phase shifters on the branch lines of the horizontal branching system according to the desired group-wise Control possibility of the phases of the individual radiators are arranged and the azimuthal Beam influencing are provided. 4. Antenna system according to claim 1, characterized in that the both branching networks have the same structure. 5. Antenna system according to claim 1, characterized by a common Transmitter and a power splitter to feed both branch networks. 6. Antenna system according to claim 5, characterized in that the Distribution of the power through the power splitter can be selected variably. 7. Antenna system according to claim 1, characterized by two independent, transmitters each feeding one of the two branching networks. 8. Antenna system according to claim 1, characterized in that the individual radiators are designed so that they are both linear and circular can emit polarized radiation. 9. Antenna system according to claim 5 or claim 7, characterized through a phase shifter in the feed line to one of the two branching networks in front of the associated vertical branching system. 10. Antenna system according to claim 5 and claim 7, characterized by a switching device with which between the operating mode according to claim 5 and the operating mode according to claim 7 can be switched. 11. Antenna system according to claim 3, characterized in that the horizontal rows are divided into several groups, and that on the leads to the individual groups phase shifters are attached, which correspond to a of two antisymmetrical, alternately switchable linear phase progressions can be adjusted along a row.