EP0017530A1 - Radiating source constituted by a dipole excited by a waveguide, and its use in an electronic scanning antenna - Google Patents

Abstract

Radiant source constituted by a dipole excited by an extra-flat waveguide. The waveguide (8) is of rectangular section, constituted by a dielectric strip (7) of rectangular parallelepiped shape, of longitudinal axis (Δ), the four faces of which are symmetrical with respect to the axis (Δ) and opposite two by two are each covered with a metal plate. The two faces parallel to the longitudinal mediator plane each extend towards the end of the dielectric strip, by a metal tab (11, 12) leading to the strands (15, 16; 13, 14) of the dipole. The strands of the dipole can be parallel or perpendicular to the direction of polarization of the electric wave radiated by the waveguide. Use in electronic scanning antennas.

Description

The present invention relates to a radiating source constituted by a dipole excited by a waveguide of rectangular section, more particularly used in antennas with electronic scanning. It also aims, as a particular application, for the production of an electronic scanning antenna.

The radiating part of an electronic scanning antenna requires a large number of repetitive elements called modules, each composed of an elementary source and an associated phase-shifter to constitute the phase-shift network.

According to a previous embodiment, such an elementary source consists of a dipole carried by a metal plate introduced at the pinched end of a waveguide by which it is excited. This embodiment has the disadvantage of having a large footprint due to the dimensions of the waveguide and the arrangement of the dipole on a metal plate. Another drawback comes from the need for machining and assembly operations leading to difficulties in industrial production, to uncertain reproducibility and at relatively high cost.

The present invention aims to remedy these drawbacks and relates to a radiating source constituted by a dipole excited by an extra-flat waveguide.

Such an embodiment meeting in particular the criterion of easy reproducibility, will make it possible to produce the radiating part of an antenna with electronic scanning.

According to a characteristic of the invention, the waveguide exciting the dipole consists of a dielectric strip of rectangular parallelepiped shape, of longitudinal axis A, the four faces of which are symmetrical with respect to the axis to and opposite two to two are each covered with a metal plate. The two sides of larger dimensions each extend towards the end of the dielectric strip by a metal tab leading to the strands of the dipole.

One of the advantages of the invention is the reduction in the size of the device constituted by the dipole and the waveguide and which is not increased by the phase shifter which is associated with it to make a module which can be used in an antenna with electronic scanning. Another advantage is the lower cost of equipment and technology.

• - la figure 1, une source rayonnante constituée par un dipôle excité par un guide d'onde, selon une réalisation de l'art antérieur ;
• - la figure 2, un type de réalisation d'un dipôle excité par un guide d'onde selon l'invention ;
• - les figures 3 à 6, quatre autres types de réalisation d'un dipôle excité par un guide d'onde selon l'invention ;
• - la figure 7, une antenne à balayage électronique comportant des sources rayonnantes élémentaires selon l'invention.

Other advantages and characteristics of the invention will appear in the description which follows, illustrated by the following figures which represent:

• - Figure 1, a radiating source consisting of a dipole excited by a waveguide, according to an embodiment of the prior art;
• - Figure 2, a type of embodiment of a dipole excited by a waveguide according to the invention;
• - Figures 3 to 6, four other types of embodiment of a dipole excited by a waveguide according to the invention;
• - Figure 7, an electronic scanning antenna comprising elementary radiating sources according to the invention.

The elements bearing the same indices in the different figures perform the same functions and are only described once.

It is much simpler to supply a dipole with a rectangular waveguide than with a coaxial line, the electric field produced in a coaxial line being radial unlike the electric field produced in a rectangular waveguide.

Figure 1 shows a radiating source consisting of a dipole 1 excited by a waveguide 2. The dipole is mounted on a metal plate 3 which fits into the opening 6 of the. waveguide 2, along the longitudinal mediator plane thereof. The strands 4 of the dipole are parallel to the direction of polarization of the electric field E propagating in the guide 2 according to the TE _.I mode for example. The metal plate 3 being introduced along the longitudinal plane of the waveguide 2, the two strands 4 of the dipole 1 are excited in the same way. The impedance matching between the dipole 1 and the waveguide 2 is done by pinching the end 5 of the guide and adjusting the depression of the dipole 1 relative to the opening 6 of the guide.

FIG. 2 represents a radiating source according to the invention. It is constituted by a dielectric strip 7 of rectangular parallelepiped shape of length L1, of width L2 and height L3 determined, of longitudinal mediating plane π and of longitudinal median axis A.

The waveguide 8 is produced from a determined length L less than LI of the dielectric strip 7, the opposite faces parallel to the plane π and the opposite faces perpendicular to the previous ones and parallel to the axis Δ are each covered by d 'a metal plate of determined length less than L1. The two metal plates 9 and 10 parallel to the plane T each extend respectively by a metal tongue 11 and 12 leading to the strands 13 and 14 of the dipole. The width of the tongues 11 and 12 decreases from the waveguide 8 towards the strands 13 and 14 of the dipole, thus achieving with the length of these same tongues the impedance matching between the guide and the dipole. In this figure the strands 13 and 14 of the dipole are coated at the end of the dielectric strip 7 perpendicular to the direction of polarization of the electric field E in the guide 8. These strands 13 and 14 are each formed by a metal strip perpendicular to the adaptive tabs and in contact with their ends. The width of these metal strips also helps the impedance matching between the dipole and the waveguide. The fact that the direction of the strands 13 and 14 is perpendicular to the direction of polarization of the electric wave emitted by the waveguide 8 causes the appearance of a cross-polarized wave. In some antenna cases, the cross-polarization residue can be used to improve detection. The waveguide 8, the tongues 11 and 12 and the strands 13 and 14 of the dipole can be obtained by metallization or photoengraving.

FIG. 3 shows another type of embodiment of a primary radiating source according to the invention. There, the strands 15 and 16 of the dipole are parallel to the direction of polarization of the electric field penciled by the waveguide. As before, the waveguide 8 and the tongues 11 and 12 can be produced by metal plates or by photoengraving, but the strands 15 and 16 are metallic tongues ensuring a certain mechanical strength.

This radiating source can serve as an elementary source of an electronic scanning antenna. In this case, it is connected to the output of one or more diode phase shifters providing the phase shift network of the antenna. In FIG. 3, the phase shifters 17, 18 and 19 respectively shifting by 3λ / 4, λ / 2 and λ / 4, each consist of a diode 20 placed in a hole 21 made in the entire thickness L3 of the dielectric strip 7. This diode 20 is connected on one side directly to the metal plate covering one of the two faces parallel to the mediator plane and on the other side to a triplate trap placed on the other face parallel to the plane so that in microwave, the diode is connected on both sides to ground.

A printed circuit 22 is connected to the phase shifters to supply them and control them. The height L3 of the dielectric strip 7 is equal to the thickness of the diodes 20 of the phase shifters.

FIG. 4 shows another exemplary embodiment of a radiating source according to the invention, in which the strands of the dipole have better mechanical strength than in the previous figure. There is on the adaptive tongue 11 or 12 a dielectric substrate board 23 of rectangular parallelepiped shape and of the same width as the adaptive tongue 11 or 12, so that its long sides 24 and 25 are perpendicular to the longitudinal mediating plane lT and such that the short side perpendicular to the plane π located at the end of the dielectric strip 7 is metallized to form the strands 26 and 27 of the dipole.

Another embodiment of the dipole strands is shown in the Figure 5. The strands 28 and 29 are constituted by metal blades machined in the shape of a T, while in Figure 6, the strands 30 and 31 have the shape of U.

FIG. 7 represents an antenna with electronic scanning where the elementary sources are produced in accordance with the invention. All the dipoles 32 are oriented in the same direction which is that of the polarization of the antenna. At a distance equal to a quarter of the operating wavelength λ / 4, reflective parts are placed, constituting the reflector of the antenna. For reasons of mechanical strength and ease of assembly, each row of dipoles 32, of longitudinal axis perpendicular to the direction of the strands of the dipoles, is surrounded on one side by a metal plate 33 of length equal to the height of the row and on the other hand by small metal plates 34 of length equal to the distance separating two dipoles. The shape of the antenna can be arbitrary, flat or parabolic for example.

There has thus been described in the form of two possible embodiments a radiating source constituted by a dipole supplied by an extra-flat waveguide, of dimensions very reduced compared to those of the prior art. Neither requiring very expensive equipment nor too great technological difficulties, the overall cost of such a source is relatively low.

Claims (17)

1. Radiant source consisting of a dipole excited by a waveguide of rectangular section, characterized in that it comprises a dielectric strip (7) of rectangular parallelepiped shape of length (L1), width (L2) and determined height (L3), the two opposite faces parallel to the longitudinal mediating plane (π) and the two opposite faces perpendicular to the preceding ones and parallel to the longitudinal median axis (Δ) of the blade are each covered with a metal plate of length (L) determined lower than (L1) thus constituting the waveguide (8), the metal plates (9 and 10) covering the two opposite faces parallel to the longitudinal mediator plane (π) each extending along the longitudinal median axis (A) by a metal tongue (11 and 12) leading to the strands (13 and 14) of the dipole. 2. Radiant source according to claim 1, characterized in that the metal tongue (11 or 12) has a decreasing width from the waveguide (8) towards the strands (13 and 14) of the dipole, thus realizing the adaptation d impedance between the waveguide and the dipole. 3. Radiant source according to claim 1, characterized in that the two opposite faces parallel to the longitudinal mediator plane (π) and the two opposite faces parallel to the longitudinal median axis (Δ) are metallized over a determined length (L) less than (L1), thus constituting the waveguide (8). 4. Radiant source according to one of claims 1 to 3, characterized in that the strands (13 and 14) of the dipole, of direction perpendicular to the electric field È radiated by the waveguide, are lying at the end of the dielectric strip (7) and consist of a narrow metal strip perpendicular to the adaptive tongue and in contact with its end. 5. Radiant source according to one of claims 1 to 3, characterized in that the strands (15 and 16) of the dipole, of direction parallel to the plane of polarization of the wave radiated by the waveguide (8), consist of a narrow perpendicular metal tab with the adaptive tongue and in contact with its end. 6. Radiant source according to claims 3 and 5, characterized in that the strands (15 and 16) of the dipole are constituted by a narrow metal insert plate, to ensure better mechanical strength. 7. Radiant source according to claims 3 and 5, characterized in that the strands (28 and 29) of the dipole are constituted by a narrow metal plate in the shape of a Tee. 8. Radiant source according to claims 3 and 5, characterized in that the strands (30 and 31) of the dipole are constituted by a narrow metal plate in the shape of a U. 9. Radiant source according to claims 1 to 3, characterized in that a dielectric substrate board (23) of rectangular parallelepiped shape and of the same width as the adaptive tongue (11 or 12) is arranged against the latter so that its long sides (24 and 25) are perpendicular to the plane (π) and that its short side perpendicular to the plane (π) and located at the metallized end to form the strands (26 and 27) of the dipole. 10. Radiant source according to one of claims 1 to 6, characterized in that the dielectric strip (7) is an air layer. 11. Radiant source according to one of claims 1 to 7, characterized in that it is used in an antenna with electronic scanning, this radiating source being directly connected to the 'output of at least one diode phase shifter. 12. A radiating source according to claim 11, characterized in that the phase shifter associated with the radiating source consists of a diode (20) placed in a hole (21) made throughout the thickness of the dielectric strip (7), this diode being connected on one side to a triplate trap placed on the metal plate deposited on a first face of the blade parallel to the longitudinal mediator plane (π) and on the other side directly to the metal plate deposited on the second opposite face to the first. 13. Radiant source according to claim 12, characterized in that the height L3 of the dielectric strip is equal to the thickness of the diode constituting the phase shifter. 14. Radiant source according to one of claims 11 to 13, characterized in that the diode phase shifter associated with the source is supplied and controlled by a printed circuit (22) placed parallel to the dielectric strip. 15. Radiant source according to claim 8, characterized in that it comprises a reflective part located perpendicularly and on either side of the dielectric strip, at a distance from the plane comprising the strands of the dipole equal to a quarter of the length d operating wave. 16. Radiant source according to claim 15, characterized in that the metal plates covering the dielectric strip (7) are made of cadmium-plated metal and the reflective part associated with the dipole is made of aluminum. 17. Antenna with electronic scanning using the primary radiating sources according to claims 1 to 16.

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