FR2488058A1 - RADIANT SOURCE COMPACT BI-BAND OPERATING IN THE FIELD OF HYPERFREQUENCIES - Google Patents

Abstract

COMPACT DUAL BAND SOURCE OPERATING IN THE HYPERFREQUENCY FIELD, COMPRISING TWO UNITS EACH CONSISTING OF A SYSTEM OF RADIANT DIPOLES 6 AND 8-9 AND BY A REFLECTOR DEVICE 7 AND 10, THE POLARIZATIONS OF THE RADIUS WAVES RESPECTIVELY RESPECTED BY THE TWO 'IN RELATION TO THE OTHER AND THE RELATIVE POSITION OF THESE TWO SETS WITH RESPECT TO THE OTHER BEING SUCH THAT THEIR PHASE CENTERS ARE MIXED. APPLICATION TO ELECTRONIC SCAN ANTENNAS AND PRIMARY SOURCES LIGHTING A FOCUSING OPTICAL SYSTEM.

Description

The present invention relates to a radiating source

  compact band operating in the microwave field.

  It is usable as a primary source illuminating a focusing optical system or as a radiating element directly, alone or as part of a scanning array antenna. Previously, a radiant source operating in two distinct frequency bands was constituted by two distinct elementary sources each operating in a band but both associated with the same reflector in the form of a dihedral, as shown in FIG. indeed a dipole 1 whose direction of the strands is parallel to the edge 2 of the dihedral reflector 3 common, and two other dipoles 4 and 5, located on either side of the dipole 1 for reasons of symmetry and whose

  direction of the strands is perpendicular to that of the strands of the dipole 1.

  The dipole 1 on the one hand and the two dipoles 4 and 5 on the other hand have cross polarizations with respect to each other and it is readily conceivable that when such a dual-band radiating source is to illuminate a focusing optical system, a parabolic reflector for example, the phase centers of the two sets, consisting of one by the dipole 1 and the reflector 3 and the other by the dipoles 4 and 5 and the reflector 3, can not be confused all both with the focus of this optical system. In this case, the phenomena of aberration do not make it possible to obtain, from such a dual-band source, the best

possible radiation.

  The object of the invention is to overcome such disadvantages and to achieve a compact radiating source, operating in two

separate frequency bands.

  According to one characteristic of the invention, this ray source

  compact dual band operating in the field of hyper-

  frequencies, comprises two source-reflector radiating assemblies, the first set being constituted by a system of dipoles tuned on the frequency band whose central frequency is the

  the higher of the two and radiating a polarization wave deter-

  coupled with a semi-transparent reflective device, the second assembly being constituted by a dipole system radiating a cross-polarization wave with respect to the previous one associated with a totally reflective device, the relative position of these two sets, one for each relationship to the other being such that their phase centers are merged. The fact that the two phase centers of the two source-reflective radiating sets are merged gives a better

  focus of the source and therefore better characteris-

radiation characteristics.

  Other features and advantages of the invention are

  in the description which follows, illustrated by FIGS. 2, 3, 4

  and which, in addition to FIG. 1 already described, represent nonlimiting exemplary embodiments of a dual-band radiating source according to the invention. Figure 2 shows a dual-band radiating source which has two distinct radiating assemblies; the first is constituted by a dipole 6, tuned to the band whose frequency

  the highest level, combined with a semi-reflective device 7

  transparent and the second set consists of two dipoles 8 and 9 associated with a second reflector device 10. The dipole 6 radiates a determined polarization wave, for which the reflector device 7 is transparent but which is reflected by the reflector 10. By cons the dipoles 8 and 9 radiate a wave whose polarization is crossed with respect to the previous one, so that the reflector 7 reflects it completely. By adjusting the relative position of these two sets that is to say by adjusting both the distance D between the two reflectors 7 and 10 that the distance d between the strands of the dipoles 6 on the one hand and 8 and 9 on the other hand , we can do

  to coincide with their phase centers so as to obtain the characteristics

  optimal radiation characteristics.

  As shown in FIG. 2, the semi-transparent reflector 7 is constituted by a network of parallel metallic wires 11 whose direction is perpendicular to that of the strands 12 of the dipole 6, therefore to the polarization of the wave that it emits. . The reflector 10 is constituted by a network of parallel metal wires 13 whose direction is parallel to that of the strands 12 of the dipole 6 to fully reflect the wave emitted by the latter. But this reflector 10 can also be made by a network of crossed metal son or a continuous metallization surface. In order to fix this bi-band source thus constituted, on a metal support for example in order to produce an electronic scanning antenna, the reflector 10 is very structured and the

  wire network 13 is formed on a plate of dielectric material

  cudgel. The latter carries metal inserts 14 for fixing the source, serves as a landing surface for the dipoles and supports the

  power divider device integrated in its rear volume.

  In the case of FIG. 2, the semi-transparent reflector 7 lets the radiated wave pass through the dipole 6 with which it is associated; but in another embodiment, it will instead be totally reflective for this wave and let pass the wave emitted by the other dip8les and whose polarization is crossed with respect to the first. On the other hand, in all cases, the semi-transparent reflector must be associated with the system of radiating dipoles tuned to the frequency band whose central frequency is

the highest.

  In FIG. 3, the semi-transparent reflector device is made in the form of a dihedron 15, constituted by two planes 16 and 17 having a common edge 18. For reasons of optimal radiation, the dipole associated with this reflector-shaped dihedron is such that the direction of its strands is parallel to the edge of the dihedron. So,

  in FIG. 3, the dipole 19 is associated with the semi-reflector

  transparent 15, its strands 20 being parallel to the edge 18 of the dihedron 15. The son 21 of the reflector 15 being orthogonal to the direction of the strands 20 of the dipole 19, the wave emitted by it passes through the dihedral without reflection before being reflected on the reflector device 22, which consists of a network of parallel wires 23 of direction parallel to that of the strands 20. As previously, the relative position of the two source-reflector radiating assemblies makes it possible to make their two centers coincide. live to get

  the best radiation conditions of the source.

  For reasons of mechanical strength the volume encompassing the two sets source-reflector that is to say between the reflector 22, the plane passing through the outer edges 24 and 25 of the dihedron 15 and parallel to the plane 22 and the four planes perpendicular to each other and to the plane 22 may be filled with low density polyurethane foam. We can also add a dielectric radome

  around this source to ensure more tightness.

  A particular application of the embodiment described in FIG. 3 has been made for a radiating source to operate in two distinct frequency bands centered on 1000 MHz and 1250 MHz. The parallel wire network 21, constituting the dihedral semitransparent reflector 15, is obtained by the photogravure process used in printed circuit manufacturing technology. The distance between the edge 8 of the dihedral and the strands 20 of the dipole 19 is equal to 0.6 λ 1, λ being the wavelength at the center frequency 1250 MHz and the angle of the dihedral is equal to 90. The other two dipoles 30 and 31 are supplied in phase or in phase opposition via a "hybrid ring 6 A / 4" type power distributor. The planar reflector 22 is constituted by a metallized dielectric plate and the distance which separates it from the strands of the dipoles 30 and 31 is equal to 0.25

  >, 'Ä' being the wavelength at the center frequency 1000MHz.

  FIG. 4 shows another embodiment of the invention, in which the two radiating dipole systems consist only of one single dipole 26 and 27 of each

  two polarizations. To respect the symmetry of the source, neces-

  To make the two phase centers coincide, these two dipoles must be centered. For this, they are mounted on a single foot 28 common to both but are fed by two separate coaxial lines 37 and 38, each connected to one of the strands 39 and 40 of the two dipoles. Again, the shape of the reflectors is arbitrary, that is to say the semi-transparent reflector 29 may be in the form of dihedron or plane just like the reflector 300, the remarks

  their relative position being the same as above

  ously. Figure 5 is considered the case where the two reflector devices 290 and 301 are made in the form of dihedral. As has been explained before, the two dipole systems having their strands perpendicular to each other, the dihedrals are arranged so that the edges 310 and 32 respectively formed by the intersection of the planes (33 and 34) and ( 35 and 36),

are perpendicular.

  Finally, FIG. 6 represents another embodiment of the invention, in which the reflector 41 in the form of a dihedral is placed

  so that its edge 42 is located behind the plane reflector 43.

  At the reflector 41 is associated a dipole 44 whose strands are parallel to the edge 42 and the plane reflector 43 are associated two dipoles 45 and 46 of cross polarization with respect to that of the dipole 44. The portion of the plane reflector 43 located forward of the edge 42 must necessarily be semi-transparent to let the wave emitted by one of the two systems of radiating dipoles, that is to say by the dipole 44 in the specific case of this figure. The other part of this reflector, like the dihedral reflector 41 itself, can consist of solid metal plates or networks

  polarizers according to the desired purpose.

  In all these cases of realization described, the Polish systems

  risers constituted by metal wire networks can be photoengraved on wafers of dielectric material. These wire networks can also be replaced by stiffer parallel metal blades. The remarks concerning the relative position of the two source-reflector radiator assemblies, their practical realization and the addition of polyurethane foam as that of a

  radome are also valid in all these cases.

  Thus, a compact dual-band radiating source has been described which can be used as a radiating element directly alone or as part of a scanning electron antenna. But this source can also illuminate a focusing optical system,

  the position with respect to the two radiant sets source-

  The reflector which constitutes it is such that the focus of this optical system coincides with their two phase centers.

Claims (13)

  A compact dual-band radiating source operating in the microwave range, characterized in that it comprises two source-reflector radiating assemblies, the first set being constituted by a system of dipoles (6) tuned to the frequency band whose center frequency is the highest of the two center frequencies of the two bands and radiating a determined polarization wave, associated with a semi-transparent reflector (7), the second set being constituted by a system of dipoles (8 and 9) radiating a wave cross-polarization relative to the previous one associated with a totally reflective device (10), the relative position of these two sets relative to each other   being such that their phase centers are merged.   2. A dual-band radiating source according to claim 1, characterized   characterized in that the semi-transparent reflective device passes the radiated wave through the dipole system with which it is associated and totally reflects the radiated wave by the second dipole system.   The dual-band radiating source according to claim 1, wherein   characterized in that the semi-transparent reflective device passes the wave radiated by the second dipole system and totally reflects the radiated wave by the dipole system with which it is associated.   4. A dual-band radiating source according to claim 1, characterized   characterized in that the semi-transparent reflective device (7) is constituted by a network of parallel metallic wires (11) whose direction is perpendicular to that of the polarization of the wave for which is transparent.   5. A dual-band radiating source according to claim 1, characterized   characterized in that the totally reflective device (10) is constituted by a network of parallel metallic wires (13) whose direction is parallel to the polarization of the wave which it reflects, or by a network of crossed wires or by a surface to continuous metallization.   6. A dual-band radiating source according to claim 1, characterized   characterized in that the semi-transparent reflective device (7) is plane.   7. Bi-band radiating source according to the re-invention 1, characteristics   erised in that the semi-transparent reflective device (15) is made in the form of a dihedral and in that the dipole or dipoles (19) associated with it are such that the direction of their strands (20) is   parallel to the edge (18) of the dihedron (15).   8. Bi-band radiator according to claim 1, characterized   characterized in that the reflector device (10) is plane.   9. Bi-band radiator according to claim 1, characterized   characterized in that the reflector device (301) is in the form of a dihedron and in that the dipole or dipoles associated with it are such   that the direction of their strands is parallel to the edge of the dihedron.   10. Bi-band radiating source according to one of the claims   1 to 9, characterized in that the volume encompassing the two radiating dipole systems and the two reflector devices is filled   of low density polyurethane foam.   11. Bi-band radiating source according to one of the claims   1 to 10, characterized in that a dielectric radome is placed around the source.   12. An electronic scanning antenna comprising an array of radiating elements each consisting of a compact source   dual band according to one of claims 1 to 9.   13. Primary source illuminating a focusing optical system, consisting of a dual-band radiating source according to one of the   Claims 1 to 9, characterized in that the position of the source   compared to the optical system is such that the two phase centers of the two sets radiating source-reflector which the   constitute the focus of the optical system.