DE19636151A1 - Phase controlled antenna for radar device - Google Patents

Abstract

The antenna has several radiators arranged together in a line configuration, with several lines one above the other in the elevation direction. The radiators are supplied with their respective signals via an elevation distribution network (EV), coupled to each line via a phase shifter and phase setting network. The phase shifter and setting network has an associated coupler (K1) with an input gate, an insulation gate coupled to a high frequency (HF) termination, and two output gates, coupled to the respective phase setting devices. There is a second coupler (K2) with input gates coupled to the outputs of the phase setting devices, with the output gates providing two signal outputs which are coupled to supply points at the end of each line.

Description

The invention is based on a phase-controlled antenna according to the preambles of claims 1 and 2.

Such an antenna, also called a group antenna, is known from DE-A-38 03 779. The one described there The arrangement consists of a predeterminable number of (Ra dar-) emitters (emitter elements), which are arranged in a matrix are arranged, i.e. in rows and columns. A broadcast as well Reception arrangement are via a send / receive um switch (circulator) and a (signal) column distribution lung, which is also called elevation distribution, to a (Signal) line distribution coupled. These are the ones Spotlight connected. Each row distribution contains one 3 dB 90 ° coupler and one of two best phase shifters double phase shifter arrangement that between the  3 dB-90 ° coupler and the emitters is arranged. In the Such a group antenna is used in general mechanically around the azimuth axis, perpendicular to the earth surface stands, rotated (swiveled). This creates in the azimuth plane, which is essentially parallel to the earth's surface surface, a mechanically swiveled transmission / reception club (send / receive diagram). This can be found in the Eleva tion plane, which is perpendicular to the azimuth plane, elec be tronically swiveled by an electronic control tion of the double phase shifter arrangement.

The invention has for its object in an antenna this type with little technical effort ten of the diagram control significantly expand.

This problem is solved by the in the characterizing Parts of claims 1 and 2 specified features. Advantageous refinements and / or further developments are the other claims.

An advantage of the invention is that also in the Azimuth plane, in addition to the mechanical pivoting of the Club (antenna diagram), an electronically switchable Swiveling the club is possible.

Further advantages result from the following Be spelling.

The invention is based on an arrangement according to DE-A-38 03 779. It is essentially only an additional 3 dB-90 ° coupler inserted in each line distribution, namely in the signal curve between the already mentioned he double-phase shifter arrangement and one Line of combined spotlights. These are arranged within the line in such a way that adjacent radiators (transmit) signals with a predeterminable phase shift (phase increment) are supplied. Such a radiator arrangement is possible, for example, with waveguide slot radiators ( FIG. 1) or with double-polarized radiators known from DE-A-39 02 739 and a so-called triplate distribution ( FIG. 4).

The invention is described below with reference to exemplary embodiments play with reference to schematically illustrated Figures explained in more detail. Show it

Fig. 1 to Fig. 5 schematically illustrated Ausführungsbei games and diagrams for explanation.

The Fig. 2a, 2b show a waveguide slot antenna HS which is cutlery are, for example, for the radar frequency range. Such a waveguide slot antenna HS consists, for example, of a waveguide with a rectangular cross section. In the waveguide several (radar emitter) slots are made on a narrow side, namely transversely (perpendicular) to the longitudinal axis and inclined alternately with respect to this. If such a waveguide slot antenna, with a terminating resistor attached AB, has a one-sided coupling of a wave whose wavelength depends on the dimensioning of the slots, an azimuth transmitter lobe SK is formed, which is deflected by an azimuth angle Φ from the normal N. is. Here, FIG takes place accordingly. 2a (as well as the transmission overlying chart) at a feed of the shaft (arrow) of the left side S1 (termination resistor (HF bottoms) AB on the right side S2) a distraction of the resulting azimuth transmission lobe SK1 to the (positive) azimuth angle + Φ1. Accordingly, Fig. 2b and the Sendedia program shown above, however, with a feed from the right side S2, a deflection of the resulting transmission lobe SK2 by the (negative) azimuth angle -Φ1. Thus, if the Einspei solution according to Fig. 2a, 2b is adjustable, then ent are in the azimuth plane about the azimuth angle Φ1, -Φ1 switchable (azimuth) transmission lobes SK1, SK2.

The arrangement is based on this (switching) property, as shown in FIG. 1. This shows a plurality of (radiator) lines arranged in the elevation direction for a transmission signal, namely a top line ZO and a bottom line ZU. Between the elevation distribution EV and each line ZO to ZU there is an associated phase adjustment and phase switching network, consisting of a first 3 dB-90 ° coupler K1, a double-phase shifter arrangement PH1, PH2 and a second 3 dB-90 ° coupler K2 . With its outputs (line) inputs S1, S2 are coupled. At a gate (isolated gate) of the first coupler K1 a Abschliesswi resistance (RF sump) AB is connected. If a transmission signal is now coupled into the input EVE of the elevation distribution EV, which is known, for example, from DE-A-38 03 779 mentioned at the outset, the resulting transmission lobe, which is emitted from the lines ZO to ZU, can be pivoted in the elevation direction by means of the phase shifter. In addition to this pivoting, the transmitting lobe can be switched in the azimuth direction in accordance with the explanations given with reference to FIGS . 2a, 2b.

The output signals SA, SB generated on the phase setting and phase switching network are explained below with reference to FIG. 3. If a (transmit) wave with the (standardized) ampli tude 1 is coupled in at the input gate ET of the first coupler K1, then (outputs) waves with an (output) amplitude arise at the outputs K11, K12 of the first coupler K1 1 / √. With regard to the input signal, the signal emerging at the output K11 has a phase shift of 0 °. The signal arising at the output K12 has a phase shift of -90 °. For the phase shifters PH1, PH2 there are now phase settings which divide the transmission power coupled into the input port ET equally between the two outputs SA, SB and others which only either (essentially completely) transmit power to the output SA or the output SB, according to the following table. There, PH1, PH2 denote the phase settings in old degrees of the associated phase shifters PH1, PH2 and SA, SB, the amplitudes that arise at the outputs and are dependent on the phase settings (standardized) amplitudes. It can be seen that when the phase shifters are in phase or out of phase, the output wave occurs either at SA or SB. The absolute value of the phase set on the phase shifters does not matter. The shown (phase) values 0 ° and 90 ° were selected for the sake of clarity.

During operation of the antenna, the phase shifters PH1, PK2 can be electronically set (controlled) at the same time in accordance with these settings, so that correspondingly switched (transmitting) lobes SK1, SK2 ( FIGS. 2a, 2b) are produced. These are swiveled in the direction of elevation in accordance with the phase differences (phase increments) set electronically on the phase shifters from line to line, the phase opposition of the two phase shifters of each line being always set identically in accordance with the table above.

The embodiment shown in FIG. 4 differs from that of FIG. 1 essentially by the configuration of the (radiator) lines ZO to ZU, of which only one is shown in FIG. 4 for the sake of clarity. Such a line arrangement is known, for example, from DE-A-39 02 739 mentioned at the beginning. Each line consists essentially of a predeterminable number of double-polarized radiators STR. These each contain two radiator elements for emitting radiation polarized perpendicular to one another. For each polarization direction there is a separate triplate distribution TV1, TV2, to which the radiator elements of one polarization direction, for example vertically or horizontally, are connected. Each of the triplate distributions TV1, TV2 is coupled via a separate line (waveguide) L1, L2 to one of the outputs SA, SB of the second coupler K2.

With such a (line) arrangement, two are now switched bare (transmission) lobes SK1, SK2 can be generated in that between the outputs of a triplate distribution, for example se TV1, and the radiator elements connected to it, for example for horizontal polarization, respectively a delay line VL is coupled. It changes the length of the delay lines VL can be predetermined Way between adjacent radiator elements, so that for the waves emitted by these a predetermined phase increment (in the azimuth direction). Between the Outputs of the other triplate distribution, here TV2, and the however, there are no radiator elements connected to it  Delay lines coupled in, so that between all no waves from these emitter elements there are differences. It can be seen that this two switchable (transmitting) lobes, in the azimuth plane, with un different polarizations (perpendicular to each other hend) of the emitted waves and predefinable angles different (in the azimuth plane) the main (send) directions can be generated.

FIG. 5 shows a further exemplary embodiment for a phase adjustment and phase switching network. In these, the double phase shifters PH1, PH2 are each replaced by a transmitter / receiver module TRM, which is common in phase-controlled antennas. Such a transmit / receive module TRM essentially contains a transmit and receive path, with the necessary transmit and receive amplifiers, and at least one phase shifter. The described order to switch the supply of the radiator elements by adjusting the phase shifter is also possible. In each of the transmit / receive modules TRM, however, the amplifiers present there must also be set such that the same output signals are produced at the (output) gates T2. In addition, the same input sensitivities and / or the same input signals must be set at the (input) gates T1, for example by means of a calibration process.

Such arrangements are applicable, for example, to a so-called acquisition radar.

The invention is not based on the embodiment described examples limited, but analogously to other applications bar.

Claims (6)

1. Phase controlled antenna, whereby

• a predeterminable number of radiator elements are combined into one line,
• a predeterminable number of lines are arranged one above the other in the elevation direction,
• - An elevation distribution network is available to distribute an electrical signal present at the input of the elevation distribution network to the rows and
• there is a phase shifter and phase control network between the elevation distribution network and each line, characterized in that
• - That the phase shifter and phasing network is formed from
  a first coupler (K1) with an input gate (ET),
  an isolated gate (IT), to which an HF termination (AB) is connected, and two output gates (K11, K12), to each of which a controllable phase adjuster (PH1, PH2) is coupled, and
  a second coupler (K2), the input gates of which are coupled to the outputs of the phase adjusters (PH1, PH2) and the output gates of which form two signal outputs (SA, SB),
• - That each line (ZO to ZU) is designed as a waveguide slot antenna ne with a predeterminable number of slot radiator elements and with feed points (S1, S2) at the ends of the line and
• - That the feed points (S1, S2) of each line are coupled to the signal outputs (SA, SB) of the associated phase shifter and phase control network.

2. Phase controlled antenna, whereby

• a predeterminable number of radiator elements are combined into one line,
• a predeterminable number of lines are arranged one above the other in the elevation direction,
• - An elevation distribution network is available to distribute an electrical signal present at the input of the elevation distribution network to the rows and
• there is a phase shifter and phase control network between the elevation distribution network and each line, characterized in that
• - That the phase shifter and phasing network is formed from
  a first coupler (K1) with an input gate (ET),
  an isolated gate (IT), to which an HF termination (AB) is connected, and two output gates (K11, K12), to each of which a controllable phase adjuster (PH1, PH2) is coupled, and
  a second coupler (K2), the input gates of which are coupled to the outputs of the phase adjusters (PH1, PH2) and the output gates of which form two signal outputs (SA, SB),
• - That each line (ZO to ZU) from a predeterminable number of double-polarized radiator elements (STR) is gebil det, the radiator elements (STR) contained in the radiator elements ent of a type of polarization are each connected to a ne triplate distribution (TV1, TV2) , and
• - That the feed points of the triplate distributions (TV1, TV2) of each line are coupled to the signal outputs (SA, SB) of the associated phase shifter and phase control network.

3. Phase controlled antenna according to claim 2, characterized ge indicates that between the outputs of a triplate Distribution (TV1) and the beam connected to it ler elements of one type of polarization each have a delay approximately line (VL) is arranged such that between those emitted by neighboring radiator elements  Waves one through the length of the delay line (VL) determinable phase difference arises. 4. Phase controlled antenna according to one of the preceding Claims, characterized in that the phase shift ber and phase control network a first 3 dB-90 ° - Coupler (K1), a double-phase shifter arrangement (PH1, PH2) and a second 3 dB 90 ° coupler (K2). 5. Phase controlled antenna according to claim 1 or claim 2, characterized in that the phase shifter and Phase control network a transmit / receive module (TRM) contains, at least consisting of send / receive Amplifiers and a phase adjuster. 6. Phase-controlled antenna according to one of the preceding Claims marked for use as acquisitions onsradar.