FR2490025A1 - Monomode or multimode radar horn - contains radiating elements deposited on thin dielectric substrate located perpendicular to direction of polarisation - Google Patents

Abstract

The device has two radar channels and includes a horn (7) supplied by a waveguide (8) to form one channel with a radiating assembly in the horn providing a second or more channels. The assembly is formed by a radiator element (9) itself formed on a dielectric substrate plate (10) which is located in the median plane of the horn perpendicular to the polarising direction of waves radiated by the horn. The assembly radiates waves whose polarisation is transverse to that of the horn waves. The plate is typically 2.4mm thick and additional plates located symmetrically about the first plate may be provided with the elements photo engraved or otherwise formed on these plates are quarter wavelength wires or dipoles of half or full wavelength or flared radiant windows. The plates may be made of epoxy glass resin. The arrangement avoids masking normally caused by dipoles added to a horn radiator.

Description

 The invention relates to an antenna of the horn, singlemode or multimode type comprising at least two radar channels and operating in the microwave domain. This antenna can be used as a radiator of electromagnetic waves radiating alone directly the radar emission signal and receiving in return electromagnetic signals or as a primary source illuminating a focusing optical system. In this case the directivity of the radiated beam is much greater than that of the source alone.

The focusing systems requiring an illuminator placed in their focus such as an antenna with two radar channels are in particular:
- parabolic mirrors or reflectors, the cut-out of which may be rectangular or elliptical;
- reflectors with double curvature in C or S; this type of reflector makes it possible to produce a cover in the particular site plan known as "in square cosecant"
- passive lenses;
- active lenses allowing electronic scanning of the space by the radiated beam;
- reflect - array or network antenna with phase shift by reflection.

 In the prior art, an antenna having two or even three radar channels was obtained using two different techniques. According to the first technique, the second radar channel is produced by two, four or even six dipoles judiciously located around the horn forming the first radar channel, that is to say in the focal region of the focusing optical system illuminated by this antenna. The polarizations of the waves emitted respectively by these two radar channels can be either crossed or collinear; in the latter case, the addition of decoupling filters is often necessary.

 The drawback presented by this technique is the mask effect produced by the dipoles added around the horn. In fact, the increase in the size of the focal plane of the illuminated reflector decreases its radiating opening, thus harming the radiation characteristics. In the case where the antenna is centered, it sometimes happens that it is impossible to achieve a second radar channel because of this mask effect which degrades the radiation characteristics too much.

 According to the second technique for producing a two-channel radar antenna, the signal from the second channel is injected inside the groove of the horn emitting the signal from the first channel. Two injection methods exist: the first consists of placing a small antenna of the cross-bar or plunger type inside the feed guide of the horn, the polarization of the wave emitted by the plunger having to be crossed with respect to that of the wave emitted by the horn. A drawback of this method comes from the fact that it is impossible to correctly focus the radiation from this second channel, the focal point of the illuminated reflector being occupied by the horn, hence a deterioration of the radiation characteristics.

 The second injection method consists in gradually modifying the section of the horn, over the entire length thereof as shown in FIG. 1. The straight section 1 of the horn 2, supplied by the waveguide 6, is in H, at every point of the horn 2, and a small antenna 3 is placed at the entrance of the horn so that the wave which rayon is propagated mainly between the edges of the moldings 4 and 5 thus produced, with a- polarization crossed by compared to that of the wave radiated by the horn. The width L of these moldings 4 and 5 is determined to allow the propagation of the wave emitted by the second radar channel but it generally interferes with poor adaptation of the first channel.

 In addition, if the phase center of the horn is in the plane of its opening, this is not the case of the phase center of the second radar source, hence the non-optimal radiation characteristics. Furthermore, to obtain correct operation of the second radar channel, the horn must only radiate according to a single propagation mode to the exclusion of any other superior mode, which is not always the case; indeed, it may be useful to add a second radar channel to a source in which several modes propagate, in the case of a multimode source.

 It may be noted in this connection that it is not possible to produce in the form of a kit such an antenna, intended to say to integrate the second radar channel into its already existing horn and making the first radar channel, since it is necessary create a new horn with a particular cross section and allowing the transmission and reception of the two radar channels.

 The object of the invention is a horn type antenna having at least two radar channels, intended to remedy the drawbacks mentioned.

 According to a characteristic of the invention, the horn type antenna comprises, located in the horn carrying out the first radar channel, a radiating assembly made up of radiating elements and their excitation lines deposited on thin plates of dielectric material, the polarizations of the waves radiated respectively by the horn and by the radiating unit having to be crossed.

 According to another characteristic, the radiating elements carried by the dielectric plates are dipoles, yagi, lines with flared slots, etc ... photoetched on plates of dielectric material.

Other characteristics and advantages of the invention will appear in the description which follows, illustrated by the following figures which, in addition to FIG. I illustrating an embodiment of an antenna according to the prior art, represent:
- Figure 2: an exemplary embodiment of a two-channel radar antenna according to the invention;
- Figures 3 to 8: different possible configurations of the radiating assembly located in the horn to make the antenna according to the invention;
- Figure 9: another embodiment of an antenna according to the invention, comprising several dielectric plates carrying radiating elements;
- Figure 10 t an embodiment of an antenna according to the invention, in which the parasitic higher propagation modes are eliminated;
- Figure II: an exemplary embodiment of an antenna according to the invention, with which are associated radiating elements external to the horn.

 FIG. 2 represents an exemplary embodiment of a two-channel radar antenna according to the invention, constituted by a horn 7, conventionally supplied by a waveguide 8 and producing the first radar channel and by a radiating assembly placed in the cornet, performing the second radar track. This assembly is constituted by a radiating element 9 deposited on a dielectric substrate wafer 10 and radiating a wave whose polarization is crossed with respect to that of the wave emitted by the horn 7. This wafer 10 is placed in the median plane of the horn for obvious radiation symmetry reasons and perpendicular to the direction of polarization of the wave emitted by the latter.

In the case of the figure, this radiating element 9 is a line with a flared slot, that is to say the distance d between the two edges 11 and 12 of the slot increases from the end where its excitation line is located. 13 at the end situated at the end of the plate 10. The excitation line is photo-etched on the plate 10 on the side opposite to the slit line 9 and is connected to the external supply device by a coaxial socket 14 placed on the horn 7. The plate of dielectric material is thin - of the order of 2, mm for epoxy resin glass - and the radiating element 9 - here the slotted line - as well as its excitation line 13 are deposited top according to conventional photogravure processes-
Thus, the practical realization of such an antenna is very easy and does not require complicated mechanical interventions - sometimes just a simple bonding of the plate along the walls of the horn - It also has the advantage of s '' easily adapt to any horn making the first radar channel, without having to modify it. The two radar channels are completely independent and it is possible to make their two phase centers coincide to increase the antenna performance, by adjusting the position of the plate inside the horn. In Figure 2, we see that part of the plate 10 is outside the opening of the horn.

 Three cases of implantation of the second radar channel in the horn are possible, it being understood that the polarizations of the two radar channels are always crossed with respect to each other.

 In a first case, the dimensions of the horn do not allow the propagation of parasitic modes greater than the propagation mode of the horn and which would be due to the excitation of the second radar channel. In this most favorable case, the radiating assembly, consisting of one or more plates of dielectric material carrying radiating elements, is simply placed in the horn and its radiation is correct.

 In a second case, the dimensions of the horn allow the propagation of parasitic higher modes generated by the second radar channel. To overcome this drawback, several metallic or dielectric plates are partially or fully metallized on either side of the active middle dielectric plate, perpendicular to the wave radiated by the horn. These metal plates being orthogonal to the polarization of the wave generated by the groove of the horn, they do not hinder the propagation of the wave radiated by the latter. This case arises during the use of a radiating slit line to constitute the box serving as shielding, in order to avoid the excitation of parasitic higher modes.

 Finally, in a third case, the dimensions of the horn prevent any propagation of a wave generated by a second radar channel. In this most unfavorable case, the dielectric plate or plates carrying radiating elements are placed and dimensioned with respect to the horn so that the radiating elements are outside the horn. Due to a modification of the initial radiation characteristics of the horn due to the presence of these radiating elements, a retouching of the dimensions of its opening makes it possible to compensate for the disturbances.

 FIGS. 3 to 8 show different possible configurations of the dielectric plates carrying radiating elements which are installed in the horn to produce the antenna according to the invention.

 In the case of FIG. 3, the radiating elements are two flared slot lines 15 and 16 deposited on one side of a dielectric plate 17, their separate excitation lines 18 and 19 being deposited on the other side. This set of slotted lines increases the directivity of the antenna.

 In FIG. 4, the two lines with flared slots 20 and 21 are excited together by a coupler 22, deposited on the other side of the dielectric plate 23 opposite the lines.

 FIG. 5 represents a radiating element constituted by a whole wave dipole 24 whose strands 25 and 26 on the one hand and 27 and 28 on the other hand are deposited respectively on one side and on the other of the dielectric plate 29. This allows better symmetry of the radiation of such a dipole. The supply line 30 for this dipole is deposited on one of the faces of the wafer. A half or quarter wave dipole can also be produced.

 FIG. 6 shows a radiating element of the second radar channel, constituted by a network of two dipoles 32 and 31 full wave.

 In FIG. 7 is shown a radiating element 33 in periodic log deposited on a dielectric plate 330 and excited by a line 331 and in FIG. 8, the radiating element is produced in microstrip technology, that is to say that on a first face of a dielectric plate 38 is deposited a metallic plane 35, called ground plane, and on a second face opposite to the first is deposited the excitation line 36 of the radiating element constituted by metal pieces 34 photo-etched and of log-periodic distribution.

 In all that has just been described, the radiating assembly carrying out the second radar path of the antenna according to the invention consists of radiating elements deposited on one or more plates of dielectric material, placed perpendicular to the direction of polarization of the wave emitted by the horn. The thickness of a plate or two plates attached to each other being much less than the operating wavelength of the first radar channel, their presence in the horn does not disturb the propagation of the wave generated by the groove of the latter .

 FIG. 9 shows an antenna according to the invention, comprising several plates 39, 40 and 41 of dielectric material, carrying radiating elements 42 of the second radar path of the antenna. These plates are arranged inside the horn 43 so as to produce a network in plane E or in plane H or mixed E and H.

Their relative position relative to the sides of the horn 43 is such that their theoretical extensions towards the guide 430 intersect at the geometric center G of the horn. In the case of this figure, the plates 39 and 41 are entirely implanted in the horn 43 not exceeding its opening 44, but this implantation is a function of the dimensions of the radiating elements relative to those of the horn.

 It is also possible to make an antenna with two radar channels by placing a part of the elements radiating the second channel on the very internal lateral walls of the horn.

 In all the embodiments, the short-circuit plane associated with the plates carrying radiating elements is placed at a quarter wave of these or at a quarter wave of their excitation line at the central frequency. of the operating band of these elements. This short-circuit plane is formed by a network of parallel metallic strips 52 carried by a dielectric plate 53 parallel to the plane comprising the opening of the horn, as shown in FIG. 10.

 FIG. 11 shows an exemplary embodiment of an antenna according to the invention, with which radiating elements outside the horn are associated. Outside the horn 45, there are associated with the radiating element 46 deposited on a dielectric plate 47 two radiating elements 48 and 49 of the same type, also deposited on plates of dielectric material 50 and 51. However, they can also be associated with elements radiant of another type, entirely metallic for example. Such an arrangement improves the radiation pattern of the second radar channel by increasing its directivity.

 Thus, an antenna of the single-mode or multimode horn type with at least two radar channels has been described, which can be used as a primary source or as a wave radiator. It is also possible to combine several of these antennas to form a linear or planar array, or even to make an antenna with electronic scanning operating in two distinct frequency bands.

Claims (14)

 1. Antenna of the single-mode or multi-mode horn type comprising at least two radar channels, operating in the microwave domain, characterized in that it comprises, located in the horn (7) performing the first radar channel, a radiating assembly performing one or more several other radar channels and consisting of radiating elements (9) and their excitation lines deposited on at least one thin plate (10) of dielectric material, the polarizations of the waves radiated respectively by the horn (7) and by the assembly radiating element to be crossed and the short-circuit plane associated with the radiating elements being placed at a quarter of their wavelength.  2. Antenna according to claim 1, characterized in that the radiating assembly carrying out the second radar channel is constituted by a single dielectric plate carrying radiating elements placed in the median plane of the horn perpendicular to the direction of polarization of the wave issued by the cornet.  3. Antenna according to claim 1, characterized in that the radiating assembly consists of several dielectric plates (39, 40 and 41) carrying radiating elements, placed on either side of the median plate (40) and perpendicular to the direction of polarization of the wave emitted by the horn (7).  4. Antenna according to claim 1, characterized in that the radiating elements carried by the dielectric plates are quarter wave strands, or half or full wave dipoles (24) or lines with flared radiating slots.  5. Antenna according to claim 4, characterized in that the radiating elements are photoetched on one or more plates of dielectric material.  6. Antenna according to claim 1, characterized in that the short-circuit plane associated with the radiating elements consists of a network of parallel metallic strips (52) carried by a dielectric plate (53) perpendicular to the dielectric plates carrying the radiating elements .  7. Antenna according to claim 1, characterized in that the thickness of the dielectric plates (10) carrying radiating elements (9) is very small compared to the operating wavelength of the first radar channel.  8. An antenna according to claim 1, characterized in that the plates of dielectric material are made of glass epoxy resin.  9. Antenna according to one of claims 1 to 7, characterized in that, at least one radiating element (48-49) outside the horn (45) is associated with one or more radiating elements (46) placed in the horn.  10. Antenna according to claim 9 characterized in that the external radiating elements are located on either side of the horn (45).  11. Primary source illuminating a focusing optical system constituted by an antenna of the horn type comprising at least two radar channels according to one of claims 1 to 9.  12. Electromagnetic wave radiator constituted by an antenna of the horn type comprising at least two radar channels according to one of claims 1 to 8.  13. Linear or planar array consisting of radiating antennas according to one of claims 1 to 9.  14. An electronic scanning antenna operating in two distinct frequency bands and constituted by a linear or planar array of radiating antennas according to one of claims 1 to 9.