FR2538960A1 - Dual-function array antenna for radar - Google Patents

Abstract

The dual-function array antenna of the invention is formed of a stack of dual-function elements 1A, 1B, 1C each formed from a single-function member of the U-shaped bearing beam type 1 supporting arrays 4, 5 of doublets 6. According to the invention, oblong apertures 17 are made in the front face 12 of the beam into which penetrate prominances 19 of like dimensions of a dielectric plate 18, the front face of this plate being completely metallised, with the exception of the forward faces of these prominances. The slots of the plate are excited by individual excitation circuits 20 fed by an energy distributor 21 of the printed circuit type. Application: dual-function radars.

Description

BI-FUNCTIONAL NETWORK ANTENNA FOR RADAR
The present invention relates to a dual-function network antenna for radar.

 Generally, when in. a radar station it is necessary to associate two antennas in the same site, for example a primary tracking radar antenna, and a secondary IFF interrogation radar antenna, these two antennas are produced separately and fixed one near the other in the site, which is very disadvantageous in applications for which the minimum space is sought.

 To reduce the overall size of the antenna pair, it has already been proposed, as described for example in French patent 78 36484, to produce a dual-function antenna by mechanically integrating the antenna.

secondary radar to that of the primary radar. However, such a dual-function antenna has the disadvantage of having to be provided originally for each particular use and of being unable to be modified (change in radiation pattern, for example), because of the one-piece structure of this dual-function antenna.

 The present invention relates to a dual-function array antenna for radar which can be easily designed from known single-function antenna structures, and the radiation pattern of which can be modified, if necessary.

The present invention also relates to a dual-function radar antenna obtained by adding elements of a secondary radar antenna to an existing primary radar antenna, and this, with the simplest modifications possible.
The dual-function array antenna of the invention is formed from a structure of array antenna of dipoles providing a first function, this antenna of dipoles being of the type with microwave elements with a carrying beam of "U" section, and the front face of each carrying beam has openings, preferably oblong, identical, aligned and regularly spaced, at a pitch generally between 0.6 and 0.8 times the wavelength of the single frequency or the frequency center of the frequency band, as the case may be, frequency corresponding to a second function, a dielectric plate with slots of shape, arrangement and dimensions substantially equal to those of said openings, being arranged in the beam so that the slots in this plate coincide with and fully engage with said openings. The network of slots of the dielectric wafer is supplied by an energy distributor circuit, advantageously produced in printed circuits on a multilayer plate, disposed in the support beam.

The present invention will be better understood on reading the detailed description of an embodiment, taken as a nonlimiting example, and illustrated by the appended drawing, in which:
- Figure 1 is a partial schematic perspective view of three stacked elements of dual-function radar antenna according to the invention;
FIG. 2 is a partial schematic rear view in perspective of an antenna element of FIG. 1, and
- Figure 3 is a front view in perspective and simplified of a dual-function radar antenna with planar arrays, according to the invention.

The dual-function radar antenna shown in Figures I and 2 of the drawing includes a primary tracking radar antenna operating at a frequency of approximately 3 CH and a secondary interrogation radar antenna lFF operating in the standard IFF frequency band
ICAO, namely around 1830 and 1090 MlIz. However, it is understood that the invention is not limited to these frequency bands, nor to such relative frequency differences.

 The dual-function antenna of the invention is designed from a known structure of primary antenna with radiating doublets. This known structure consists of a stack of beam microwave elements supporting two linear networks of dipoles, these networks being parallel to each other. In Figures 1 and 2 there is shown schematically such a microwave element lA structured around a metal beam 1 produced by extrusion. The beam 1 has a cross section having a general shape in "Us', This beam, being the piece mistress good mechanical strength of a microwave element, is provided with appropriate reinforcements and ribs, only one of these ribs, referenced 2, having been shown in FIG. 2.

 The longitudinal opening of the beam 1 is closed in a sealed manner by a plate 3 serving as reinforcement for the beam 1. Means, not shown in the drawing, ensure the tight closure of the beam 1 at its two ends.

 The beam 1 serves to support two laminate assemblies 4.5 with linear arrays of flat dipoles. These networks are produced according to the known technique of triplate circuits, however, it is understood that the invention can be applied to primary radar antennas composed of linear networks produced by other techniques, provided that these networks are supported by beams similar to beam 1 described here. In order not to overload the drawing, only one dipole 6 of the set 5 is represented. The technique for producing such dipoles, being known, it will simply be recalled that they are formed by printing patterns in "L" on three superimposed planar dielectric supports, referenced 7 as a whole, arranged between two insulating plates 8, 9. The laminated assemblies 4 and 5 are suitably fixed on the external faces of the lateral parts 10, 11 parallel to one another, of the beam 1, and are therefore parallel to each other, the front parts of these assemblies, that is to say those comprising the dipole networks, projecting in front of the central part 12 of the beam 1. The parts posterior of the dielectric supports 7 of the assemblies 4 and 5 comprise energy distribution circuits (not shown) for the corresponding dipoles, these distribution circuits can for example be of the "candlestick" type. Cover plates 13, 14 are fixed parallel to the assemblies 4 and 5, by means of bracing profiles, of which only the two most anterior 15 and 16 respectively, have been shown in the drawing. The front faces of the sections 15, 16 and the front end faces of the plates 13, 14 are coplanar with the front face of the part 12 of the section 1. The front face of the element 1A is protected by a radome (not shown) connected sealingly to plates 13 and 14.

 A plane network of dipoles is obtained by superimposing linear networks of elements such as element 1A. In FIG. 1, elements 1B and 1C have been sketched fixed respectively on and under element 1A. If the length of the elements of a linear network is insufficient, we can add others and fix them end to end.

 To make the secondary radar antenna, oblong openings 17 are aligned in the part 12 of the beam 1 aligned and regularly spaced at a pitch substantially equal to 3/4 of the wavelength of the frequency 1FF of the secondary radar. The longitudinal axis of these openings is preferably coincident with the longitudinal axis of the part 12 of the beam 1. The dimensions of the openings 17 are those of conventional slots operating in the same frequency band, i.e. say that their length is of the order of half the wavelength of the central frequency of the frequency band considered, and that their width is equal to a small part of their length, for example 1/10.

 The openings 17 cooperate with a dielectric plate 18 with individually excited slots. The plate 18, made of dielectric material such as epoxy glass having a dielectric constant of approximately 4, has on its front face, that is to say that intended to be applied against the internal face of the central part 12 of the beam 1, protrusions 19 having the same shape, dimensions and arrangement as the openings 17. The entire front face of the plate 18 is metallized, including the lateral surface of the protrusions 19, with the exception of the front faces of these protrusions . The protrusions 19 fully engage in the openings 17, and their front faces are therefore in the same plane as the front face of the part 12 of the beam 1.

 On the rear face of the wafer 18 circuits 20 of individual excitation of the slots of the wafer are printed (these slots being materialized by the non-metallized front faces of the protrusions 19). These excitation circuits can for example be, as shown in the drawing, known circuits of the "ribbon line" type. Each circuit 20 is then in the form of a "T", the horizontal part of which has substantially the same dimensions as a slot and is arranged parallel to the slot, slightly higher than this slot. The vertical part of the "T" extends to the bottom of the plate 18 to be connected to a microwave energy distribution circuit. The distribution circuit is produced in a manner known per se using a rigid multilayer plate 21 carrier of the printed circuit 22, the drawing of which represents the energy distributor supplying the slots 19, by means of the excitation circuits 20, according to determined amplitude and phase laws, well known to those skilled in the art. 'art. The plate 21 is mechanically fixed to the plate 18, with respect to which it is orthogonal, by mechanical assembly means, for example by embossing and gluing. The printed circuit 22 is connected to the circuits 20 by conventional welding. The embodiment of the slots described above does not require conductive plates for separation between the successive slots of a beam element, on the rear side of these slots, the excitation circuits of these slots being sufficiently decoupled from each other, which simplifies the production of the antenna all the more.

 The metal plate 3 for closing the beam 1 also serves as a short-circuit plane for the whole of the linear network formed by the alignment of the radiating slots 19, comm% and to this effect it is placed at about a quarter of IFIF wave of the plan of this network. Of course, the dimensions of the beam 1 are such that the closure plate 3 is effectively located in the short-circuit plane of said linear network, that is to say that when the beam 1 is produced, it must be know the frequency of operation of the secondary radar. If this was not the case, for example when it is necessary to install a secondary radar antenna in an existing primary radar antenna of the type described above and not provided for the origin for such use, or when the frequency band of the secondary radar is liable to be modified, means are provided, the realization of which is obvious to those skilled in the art, making it possible to fix the plate 3 in one or more other positions, by associating it, if necessary with means for reinforcing the beam 1.

 The plate 3 is pierced with a hole allowing the fixing of a coaxial socket 23, disposed at the entrance of the circuit 22, and connected to the latter by welding. When a dual-function linear network is produced by fixing several elements end to end such as element 1A described above, the energy distribution circuits of these elements can be linked together by a similar power division circuit. to circuit 22, the various outputs of this power division circuit being connected to the sockets 23 of the various elements located downstream.

 When elements such as element 1A are stacked, as shown in FIG. 1, one can have a slit plate 18 with its energy distributor 22 in each of these stacked elements or in some of them, depending on the desired radiation pattern. To allow electronic scanning of the lFF antenna, the condition to be respected is to insert phase-shifting means in each of the lines supplying the slots or a small grouping of slots.

 If necessary, the secondary radar antenna lFF can be provided for two different frequency bands, when it is necessary to pass from one of these two bands to the other on an antenna already installed. We then practice in the front parts 12 of the beams l two series of openings 17 corresponding to these two frequency bands, and we manufacture two corresponding series of slit plates 18 with their plates 21 for supplying energy, the closing plates 3 can be fixed in two different positions as already specified above. The transition from one to the other frequency band is done simply by exchange of the plates 18 and their plates 21 and modification of the location of the planes of short circuit 3, and possibly modification of the energy distribution circuits to the various beam elements of a network.

 The linear arrays of dipoles and the linear arrays of slots of the bi-function antenna of the invention being parallel to each other, their respective polarizations are orthogonal to each other, which makes it possible to have a good decoupling of the two functions of the antenna, even if their operating frequencies are equal or similar.

 According to a variant of the invention, not shown, the slots of the secondary radar antenna may have a different shape, for example in a spiral.

 There is shown in Figure 3, in a very simplified manner, an example of dual-function antenna architecture according to the invention. The dual-function antenna 24 has an upper part 25 that is single-function and a lower part 26 that is dual-function. The upper part 25 is composed of a stack of a large number of linear arrays of doublets, for example at least sixteen, each linear array itself consisting for example of three elements with doublets fixed side by side. Part 26 is made up of a wider and less high stack of bi-function linear networks, for example half as high as the stack of part 25 b parts 25 and 26 have the same plane of symmetry. Each of these bi-function linear networks is formed for example of five elements such as element 1A. These elements can each comprise for example four or eight or even slots, the total number of slots of a linear network being determined by in a conventional manner as a function of the radiation characteristics which it is desired to obtain from the secondary radar antenna, and the number of slots per element being limited mainly by the size in depth of the energy distribution circuit supplying these slots, the distance of a quarter wave between the inner face of the part 12 of a support beam and the plane of the short circuit 3 limiting this depth.

 Of course, the antenna according to the invention may as well be a planar array as a linear array or a polyhedron-shaped array.

 In conclusion, the present invention makes it possible to produce, from a single-function antenna, a dual-function antenna without calling into question the structure of the single-function antenna in which the second antenna is implanted, this implantation being carried out economically. through the use of a single type of carrier element.

Claims (8)

 1. Dual-function array antenna for radar comprising a structure of array antenna of doublets ensuring a first function, this antenna of doublets (6) being of the type with microwave elements with carrier beam (1) with "U" section, characterized by the fact that the front face (12) of each carrying beam has identical openings (17) aligned and regularly spaced, at a pitch substantially equal to 3/4 of the wavelength of the single frequency or of the central frequency of the frequency band, as the case may be, frequency corresponding to a second function, a dielectric plate (18) with slots (19) of shape, arrangement and dimensions substantially equal to those of said openings, being arranged in the beam so that the slots of this plate coincide with said openings.  2. Antenna according to claim 1, characterized in that the openings and the slots have an oblong shape.  3. Antenna according to claim 1 or 2, characterized in that the network of slots of the dielectric plate is supplied by an energy distribution circuit (21), advantageously produced in printed circuits (22) on a multilayer plate, arranged in the supporting beam.  4. An antenna according to any one of the preceding claims, characterized in that the dielectric plate, made of dielectric material such as epoxy glass, has on its front face protuberances (19) having the same shape, dimensions and arrangement as the openings of the support beam, the entire front face of the plate being metallized, including the lateral surface of the protrusions, at With the exception of the front faces of these growths.  5. Antenna according to claim 4, characterized in that the rear face of the dielectric plate comprises individual excitation circuits (; or) slots produced by printing, each of these excitation circuits advantageously being of the "line" type ribbon "T" shaped whose horizontal part has substantially the same dimensions as a slot and is arranged parallel to the slot, slightly higher than this slot.  6. Antenna according to any one of the preceding claims, characterized in that the closure plate (3) of the support beam serves as a short-circuit plane of the slots and is located approximately a quarter of the wavelength of said single or central frequency of the plane of these slots.  7. Bi-function network antenna characterized in that it is formed of a stack of linear bi-function networks each formed from several elements produced according to any one of the preceding claims.  8. Bi-function network antenna, characterized in that it is formed partly of a stack of single-function linear networks, and partly of a stack of bi-function linear networks each formed of several elements produced according to any one of the preceding claims (24).