NL8002314A - CROSS-DIPOLO SERIES WITH A REFLECTOR. - Google Patents

Description

VO 251

Cross dipole series with a reflector

The invention relates to a cross-dipole array with a reflector, and serving to emit a composite circularly polarized wave from two linearly polarized waves.

At high altitudes in the atmosphere there existed several ionized layers containing large numbers of free electrons and positive ions. The ionization generally arises as a result of the so-called photo-effect, in other words through the action of short-wave, ultra-violet solar radiation, which is absorbed without interruption at such high altitudes in the atmosphere Since the air density at such high altitudes is extremely low, the charges recombine very slowly, ζσ & ΐ a high equilibrium value of the ionization is created. it disappears so slowly that a remnant remains over the entire night.

During the day a subdivision into three layers is possible, which 15 layers are indicated by D, E and F. For the extension of electromagnetic waves, the outer P layer, which is designated as F-2 layer, is decisive. The ionization state does not follow a simple law. The course of the day varies greatly depending on the season, longitude and latitude.

20 Wireless connectivity to satellites and spacecraft requires accurate knowledge of the outer ionosphere and magnetosphere properties. To investigate this, techniques based on incoherent scattering (scattering) are used. To this end, short-wave radiation is emitted into the atmosphere using a high-power transmitter and an antenna with a strong beam effect. Some of the emitted energy is returned to the transmitter site through the cloud-like top of the E layer after reflection at the F-2 layer in the form of scattered radiation. From the size of the scattered radiation (back-scattering) returned, inferences can be made regarding the quality of the F-2 layer. The rotation of the polarization direction is of particular importance here. For the investigation of the outer ionosphere, antennas with a strong beam effect are therefore required and which antennas can emit waves with all kinds of polarization directions, such as linear (horizontal, vertical), circular counterclockwise, circular 800 2 3 14 jsr -2- clockwise and receive.

However, not only for examining the ionosphere with the aid of radar equipment, but also in other cases, for example for suppressing echoes caused by downpours, radar equipment for purely circular polarization is required.

Moreover, for wireless connections, in particular with satellites and spacecraft, it is preferable to use waves which are circularly polarized.

It is known, for example, to use cross dipoles for radiating linear XO or circularly polarized electromagnetic waves. When it is desired to obtain a highly beamed radiation diagram, multiple of such cross dipoles arranged in a row for a reflector should be provided.

However, the diagrams valid for the two dipoles for longitudinal (calculated in the direction of the column-aligned dipoles) and for the transverse (in a plane perpendicular to the column-aligned dipoles) are not equal. Rather, the longitudinal polarization diagram in a plane perpendicular to the column-aligned dipoles has a larger radiation width. However, such an antenna is for example for the bottom. look for the outer ionosphere not suitable. More specifically, it is therefore not possible to use a cross dipole array to obtain a strong directional characteristic and as a primary radiator for a mirror antenna. Rather, in order to obtain a strong surface action for circular polarization, it is required that the radiation diagrams in a plane perpendicular to the focal line have the same shape for both polarization directions.

It is therefore an object of the present invention to provide a cross-dipole series with a reflector and serving to emit a circularly polarized wave composed of two linearly polarized waves, whereby it must be possible to use the two linear polarizations for simple linear means. in a plane extending perpendicular to the direction of the column-aligned dipoles, radiation diagrams with the same shape can be realized, while in conjunction with a mirror, a particularly high surface effect with favorable mirror dimensions and a good circular polarization of the total antenna are possible 800 2 3 14 ►> -3-. In addition, an adjustment must be made to the impedance difference between the dipoles radiating with longitudinal and transverse polarization.

Such an objective is achieved on the basis of a cross-dipole series of the aforementioned type, thereby achieving that the reflector serving for the transverse polarization is designed as a flat reflector, which by applying guide elements for the longitudinal polarization as MComer reflector "is implemented.

An important advantage which results from the invention consists in particular in that by adjusting the shape of the two radiation diagrams obtained by the longitudinal and transverse dipoles, in a plane extending perpendicular to the column-aligned dipoles, a circular polarization with a high effective effect is obtained. When a cross-dipole array constructed in accordance with the invention is used as the primary radiator of a cylinder parabolic antenna with decentralized power supply, a considerably better surface effect is obtained. When a cross dipole array according to the invention is used as the primary radiator, smaller antenna mirrors can be realized. In particular for VHF antennas with large mirror diameters, application of the present invention can lead to significant material and cost savings. Moreover, by eliminating the impedance difference between the dipoles for the longitudinal and the transverse polarization, the overall effective operation of such antennas is increased.

In further explanation of the invention, two embodiments thereof will be discussed below with reference to the drawing. 3 & drawing is: Fig. 1a is a side view or a section of a cross dipole series according to the invention; Fig. 1b is a top plan view of the configuration shown in Fig. 1a and Fig. 2 shows a cylinder parabolic antenna in which the cross dipole array 35 according to the invention has been used as the primary radiator.

In the configuration shown in Figs. 1a and 1b, a number of cross-dipoles 1,2, ..... i, ...., n arranged in a row are arranged on a flat reflector 11. Symmetrically and parallel to the 800 2 3 14 -1 + - ϊτ column-aligned dipoles of the cross dipoles 1,2, i, n, extend rod-like guide elements 21, 22 carried by owl? dielectric material formed supports 23 and 2k, which guide elements are located at a distance h above the reflector 11.

The distance h, as well as the distance a between the rod-shaped guide elements 21, 22 and the column-aligned dipoles, it is preferably equal to 0.1 + 5 times the operating wavelength "λ. The mutual distance between the cross-dipoles 1,2, uj ii ·» · ^ N is 0.7 times the wavelength 2 · Parallel to the column-aligned 10 dipoles of the cross dipoles 1,2, ....., i, ...., n are further rod-guiding elements 31 and 32, which are electrically conductively connected to the shielding outer dagger or the symmetry of the cross dipoles 1, 2, ..., i, ..., which further guiding elements are further a short distance from the reflector 11. An electrical connection is / is not unconditionally required, however, the distance to the reflector 11 is preferably about 0.1 times the operating wavelength 3. The diameter of the rod-shaped guide elements 21, 22, 31, 32 is about 0.025 times the operating wavelength 7 \. The length of the stand G-shaped guide elements 20, 21, 22 and 31, 32 are approximately the same size as those of the reflector 11.

The configuration shown in Figure 2 is illustrative of another exemplary embodiment of a cross dipole array arranged according to the invention, which functions as the primary radiator of a cylinder parabolic antenna. In addition, the dipoles of the cross dipoles 1,2, ...., i, ...., n serving for radiating the longi-tudinally polarized waves are placed in the focal line of the cylinder parabolic reflector 12, while the poles of the cross dipoles 1,2, ...., i, ...., n serving transversely polarized wave are arranged perpendicular thereto. The main radiation direction of the circularly polarized electromagnetic waves is given by the direction of the cylinder parabolic reflector 12. In this embodiment, the dimensions of this cylinder parabolic reflector 12 were chosen such that the ratio between the length of the reflector calculated in the focal line and the perpendicular thereto the diameter is approximately 0.1 + 5. As a result, in addition to a high mechanical stability, an optimum surface effect of the antenna of approximately SQ% is achieved with the provision of uniform energization of the cross dipole series.

800 2 3 14 4 -5- Η

In order for a cross-dipole array according to the invention to be effective for radiating a circularly polarized wave, it is necessary to use a polarity-dependent reflector, that for the transverse polarization as a flat reflector and that for the longitudinal polarization simultaneously acts as "Corner reflector1". This is achieved by arranging the rod-shaped guide elements 21, 22 above a flat reflector 11. These rod-shaped guide elements 31, 32 serve as impedance adaptation for the longitudinal and transverse dipoles.

These elements act as a shift of the reflector 11 for the longitudinal polarization, but without affecting the impedance and the radiation diagram for the transverse polarization. The influence of the guiding elements 31,32 on the radiation diagram for the longitudinal polarization is negligibly small.

A cross dipole array according to the invention is particularly suitable for use as a primary radiator for mirror antennas with a focal line or a focal plane.

800 2 3 14

Claims (7)

1. A cross-dipole array with a reflector and serving to emit a circularly polarized wave composed of two linearly polarized waves, characterized in that the reflector (II) for transverse polarization is used as a flat reflector and simultaneously therewith by applying of guiding elements (21, 22), for the longitudinal polarization, is designed as a "Coraer reflector". Cross-dipole series according to claim 1, characterized in that the guide elements (21, 22) are rod-shaped, these elements running symmetrically and parallel to the column-aligned dipoles of the cross-dipoles (1,2, ..., i). , ..., n) are arranged, and these elements run parallel to it at a certain distance from the reflector. Cross dipole array according to claim 2, characterized in that the guiding elements (21, 22) are arranged at a distance (h) above the reflector (11), which distance is less than half the operating wavelength (X) of the cross dipoles ( 1,2, ..., i, ... n). Cross dipole array according to claim 3, characterized in that at a distance from the cross dipoles (1,2, ..., i, ... n) equal to a quarter of the operating wavelength, with respect to the reflector, on each side of the column-aligned dipoles a rod-shaped guiding element is arranged at a distance (a) equal to 0.5 times the operating wavelength (Λ), and the distance (h) at which these two guiding elements are located from the reflector also equal to 0.005 times the operating wavelength (X). Cross-dipole series according to one of the preceding claims 1 to k, characterized in that further rod-shaped guiding elements (31, 32) are arranged in the same manner on both sides and parallel to the column-aligned dipoles, which further guiding elements are at a small distance from the reflector (II) 30. Cross dipole array according to claim 5, characterized in that the additional rod-shaped guide elements (31, 32) are preferably located at a distance of approximately 0.1 times the operating wavelength (λ) from the reflector. 800 2 3 14 -7- 'ft's. Cross dipole series according to any one of the preceding claims 2 to 6, characterized in that the rod-shaped guide elements (21, 22; 31, 32) have a diameter with an order of magnitude of 0.025 times the operating wavelength (λ). Figure 8, Cross dipole series according to one of the preceding claims 1 to 7 », characterized in that the length of the guide elements (21, 22; 31, 32) is the same as that of the reflector (11). Cross dipole series according to one of the preceding claims 1 to 8, characterized in that the cross dipoles (1,2, ...., i, ...., n serving for radiating the longitudinally polarized waves) ) are arranged parallel to the focal line of a cylinder parabolic refleet (12), and the dipoles of the cross dipoles serving as radiating transversely polarized waves (1, 2, ..., i, ..., n) arranged perpendicular thereto, the principal direction of radiation being given by the direction of the cylinder parabolic reflector (12). 80 0 2 3 14