DE3206517A1 - Microwave antenna array - Google Patents

Abstract

A teaching is specified for calculating the phase values for each aerial element of the antenna array required to generate a desired antenna directional characteristic, it being assumed that, for given amplitude shading, only the phase shading has to be calculated as the variable. In the past, it was only known for the beam deflection and beam widening to be achieved by phase control of aerial elements. A more wide-reaching beam modification, that is to say beam forming, is made possible for the first time by the invention. The invention can be used, for example, in electronically phase-controlled radar antennas. <IMAGE>

Description

Microwave group antenna

The invention relates to a microwave array antenna according to the preamble of claim 1.

From the "Radar Handbook" by Skolnik, McGraw-Hill Company 1970, pages 11-1 ff. The possibility is known, a pure beam broadening with a group antenna to be achieved by phase control.

The NATO report by AC / 243 (panel X / RSG.3), "Aspects of Phased Array Antennae in Air Defense Radar System Applications from January 1978 gives an overview about the possibilities of beam deflection and beam broadening with phase-controlled Antennas.

DE-PS 20 40 018 and DE-OS 29 43 359 deal with the application the beam broadening by means of phase control depending on the elevation angle respectively.

from the time.

It is therefore to be regarded as known that by controlling the phase occupancy a group antenna whose diagram can be influenced. One linear over the Aperture increasing phase occupancy leads to a beam deflection, whereas a symmetrical, non-constant phase occupancy across the aperture a beam broadening results. The combination of both assignments widens the beam and deflects it. The for.

Beam broadening required symmetrical phase 7 copies 4. Execution assignments are for the antennas known up to now with regard to the broadening of the main lobe and with regard to the side lobe behavior the resulting directional characteristic has been selected empirically.

The previously known systems thus include a more extensive beam change (Beam shaping) through sole phase control with a fixed amplitude occupancy the end. In order to achieve an unbalanced diagram, an unbalanced one is also used Phase assignment required. This phase allocation required for beam shaping can cannot be calculated with the previously known methods.

The object of the invention is to create a way with which for any desired directional characteristics of the group antenna for each individual radiator element can determine the required phase value and specify, wherein a given amplitude occupancy is assumed.

According to the invention, which relates to a group antenna according to the preamble of claim 1 refers, this object is achieved by applying the in the characterizing Part of claim 1 specified measures solved.

The problem of shaping the directional characteristic can then be solved, for example an antenna for adaptation to the different operating modes of a radar device to solve. The formation of the directional characteristic must namely by sole control the phase assignment of the antenna. Nevertheless, the shape of the directional characteristic should be used be freely selectable.

The possibility of beam shaping, which can be achieved by the invention without can be further implemented, offers a number of advantages, such as adaptation the directional characteristic in the direction of elevation to the terrain for minimization of clutter and soil influences, the restriction of the airspace to be monitored at a certain level, for example by means of a cosec2 diagram, the coverage a freely selectable elevation range through sector diagrams with simultaneous Restriction to a certain height or a high degree of flexibility in the search process for search time optimization by increasing the detection probability and renewal rate by adapting the antenna diagrams to the search target area.

The invention is explained in more detail below with reference to seven figures. 1 shows a desired secondary power diagram, and FIG. 2 shows the power occupancy diagram a line source realized by a radiator element column, FIG. 3 shows the block diagram an arrangement for beam shaping with a line source by means of delay lines, 4 shows the block diagram of a radiation-fed phase-controlled antenna with electronic phase shifters, Fig. 5 is the block diagram of a line-fed phase-controlled antenna with electronically adjustable phase shifters, Fig. 6 a cosec diagram generated with an array antenna according to the invention 2, and 7 shows the phase occupancy over the group antenna aperture determined on the basis of the invention for generating the diagram shown in FIG. 6.

The starting point of the calculation according to the invention is the so-called "Power-Pattern Synthesis. This method creates the desired secondary diagram defined as a performance diagram, regardless of phase. In Fig. 1 is as Example of a desired power secondary diagram shown, with on the abscissa the elevation angle 2 and on the ordinate the power level P2 is plotted.

The amplitude allocation of the individual radiator elements of the phase-controlled Antenna group is known. The ones to achieve the required secondary diagram required phase allocation is to be calculated. A single column of the radiator elements corresponds to a line source with a known power allocation. An example for Such a known occupancy is shown in FIG. 2, where x is the location coordinate and P1 is the power level. a is the geometric column length.

To solve the problem, the elevation angle as a function of x must be given. To derive the relationship, let P1 (x) be the occupancy of the line source.

The excitation power is then proportional to P1 (x) dx (Fig. 2) and P2 (2) cos d ~ »the power per unit angle in the radiation diagram (desired Secondary diagram in Fig. 1).

According to the law of conservation of energy, the energy content of the exciting section is equal to that of the radiated wedge. The equation then applies K is a constant that depends on the normalization of the diagrams. It is determined by the condition that the entire excitation power is emitted in the required range (2 os J 2) of the resulting diagram.

With O <x # a and 20 # # <# 2 we get Kzu The principle that the entire excitation power in area (0, a) must be converted into the corresponding area (J ob # 2) leads to the relationship This integral equation provides the relationship between an element of the phased array antenna and a direction in the far field. The solution is performed numerically and gives the elevation angle # &# as a function of x. The numerical solution enables any combination of primary assignment and secondary diagram.

The phase difference can now be derived from the relationship # = f (x) calculate between two radiator elements.

- = (xn - Xn-1) sin with au = phase difference = n - n-1 Xn - Xn 1 = Distance between the radiator elements n and n-1.

The phase assignment you are looking for results in with N = number of radiator elements in a column.

With these calculated values, the desired directional characteristic can now be achieved can be achieved.

The invention is applicable to flat-plate antennas, to line sources without and in connection with reflectors and on electronically phased antennas.

The setting of the calculated phase values for shaping the directional characteristic takes place with antennas without variable phase shifters by delay lines for each individual spotlight.

An example of this is shown in FIG. 3. A transmitter / receiver 1 is here connected to a power distributor 2, its output lines Via a plurality of delay lines 3 with the radiator elements one Line source 4 are connected. The line source 4 forms the in this example Emitter element column.

For group antennas with changeable electronic phase shifters the calculated phase values are set to shape the directional characteristic by controlling these phase shifters and adjusting to the calculated values. Two examples in this connection are shown in FIGS. 4 and 5. In the arrangement according to Fig. 4 it is a radiation-fed phase-controlled antenna, whereas, according to FIG. 5, the phased antenna is line fed.

According to FIG. 4, a transmitter / receiver 5 is used as a horn 6 trained primary radiator connected to the collector side 7 of the radiator elements exposed to radiation. Emitter radiators are located on the aperture side of the group antenna 8, which are connected to the collector side 7 via electronically controllable phase shifter 9 are connected. The ones required for each emitter element on the emitter side 8 Phase values are stored in a phase memory 10 and can be used for any application can be called up by a system controller 11. The device for control the phase shifter 9 is denoted by 12. In the arrangement according to FIG. 5 takes place the feeding of the radiator elements 14 and the phase shifters connected upstream of them 15 via a line-wise connected power distributor 16, which is connected to a Transceiver 17 is connected. Here, too, are for each of the radiator elements 14 required phase values are stored in a phase memory 18 and can for each application by the system control 19 called will. The control device for the phase shifter 15 is in this example denoted by 13.

A change and extension of the diagram selection of the group antenna can be changed by exchanging memory modules, e.g. PROMs in the phase memory 10 or reach 18.

Fig. 6 shows a cosec2 diagram, which with a phase-controlled Group antenna is to be generated according to the invention and then exclusively is achieved by phase variation. The degrees and are on the abscissa the level values in dB are plotted on the ordinate. Such a thing can be achieved Diagram with a phase assignment running according to FIG. 7 over the aperture. The element numbers from 1 to 76 on the abscissa and those on the ordinate Phase values 0 to -40n plotted. This phase assignment is with the help of the teaching given in the invention has been determined. For comparison, it is shown in dashed lines in FIG the diagram of a so-called "pencil beam" shown, the occurs when a constant phase occupancy across the aperture of the radiator elements is set.

9 claims 7 figures Blank page

Claims (9)

Patent claims 1. Microwave group antenna consisting of a large number of individual radiator elements, the beam shaping of which is carried out for a given amplitude occupancy by controlling the phase occupancy of the radiator elements distributed over the antenna aperture, characterized in that in a radiator element column, each representing a line source, the following condition for setting the x-location-dependent phase assignment x applies where Ä is the operating wavelength, n is the number of a radiator element in the relevant column, starting from the first radiator element at the edge of this column, N is the number of all radiator elements in this column, Yn'Yn, 1 is the geometric distance between the nth and n-1 -th radiator element and the relationship between the location x of a radiator element and a direction # n in the far field results from the following, numerically solvable integral equation: where P1 (x) is the function of the power consumption as a function of the distance x to the first radiator element, P2 (#) cos 2 is the desired secondary power diagram as a function of the angle ft and K is a constant which is defined as follows: where a is the entire column length and by and) 2 that angular range is limited in which the total power of the radiator elements of this column is emitted. 2. Group antenna according to claim 1, g e k e n n -z e i c h n e t d u r c h training as an electronically phased antenna. 3. Group antenna according to claim 1, g e k e n n -z e i c h n e t d u r c h training as a so-called flat-plate antenna. 4. Group antenna according to claim 1, g e k e n n -z e i c h n e t d u r c h training as a line source 5. group antenna according to claim 4, g e k e n n -z e i c h n e t d u r c h training as a line source in radiation connection with a reflector. 6. Group antenna according to one of the preceding claims, in which no changeable phase shifters are provided, d u r c h g e k e n n -z e i c h n e t that to adjust the calculated Phase values Delay lines (3) provided in the feed path of each individual radiator element are. 7. Group antenna according to one of the preceding claims, in which variable phase shifters are provided by way of the radiator element feed, d a -d u r c h e k e n n n z e i c h n e t that the setting of the calculated Phase values by controlling the phase shifters (9, 15) and adjusting to the calculated Values takes place. 8. group antenna according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the phase values required for each radiator element in one Phase memory (10, 18) stored and by a system controller (11, 19) for each use case can be called up. 9. Group antenna according to claim 8, d a d u r c h g e k e n n z e i c h n e t that the phase memory (10, 18) exchangeable memory modules, for example contains so-called PROMs.