FR2705169A1 - Two-dimensional array antenna, with transmitter-receiver modules distributed over the surface of the antenna, and with electronic scanning - Google Patents

Abstract

This two-dimensional array antenna, with transmitter-receiver modules (5i) distributed over the surface of the antenna, and with electronic scanning, of the type with radiating elements (6j) grouped together into waveguides (1i) each associated with a transmitter-receiver module, further includes, arranged in front of this array, an active lens (2) able to create electronic scanning in the plane E of the electric field which it receives, preceded or not preceded by a polarisation-rotating grid (3) according to whether this electronic scanning is in the plane E of the electric field or in the plane H of the magnetic field. Application particularly to radar.

Description

TWO-DIMENSIONAL, MODULAR NETWORK ANTENNA
SURFACE TRANSCEIVERS
ANTENNA, AND ELECTRONICALLY SCANNED
The present invention relates to a two-dimensional array antenna, with transceiver modules distributed over the surface of the antenna, and with electronic scanning.

 I1 is known that an antenna with transceivers distributed over its surface, also called active antenna, has many advantages, such as: use of semiconductor components compatible with a high level of integration, reliability, flexibility of use due in particular to the possibility of simply making an electronic scanning antenna or a multibeam antenna.

 This type of antenna can be produced in the form of a two-dimensional array of radiating elements, each associated with a transceiver module comprising transmit and receive amplifiers, and amplitude and phase.

 This principle however encounters in practice limitations which are on the one hand the current unavailability of the components, for want of having reached a sufficient degree of miniaturization and on the other hand the high cost of such an embodiment. Indeed, for a medium-sized antenna, for example 20 X (S being the wavelength used), it would take about a thousand transceiver modules distributed over the surface of the antenna. Such an antenna is therefore not currently feasible. For certain applications, it is known that a compromise can be found by associating a transmitter-receiver module no longer with each radiating element but with a group of radiating elements arranged according to a given dimension and radiating via a common waveguide. Using the previous example of a 20 X antenna, the number of transceiver modules is reduced to less than 80. The construction of the antenna is considerably simplified while retaining the main advantages of the active antenna mentioned above.

 As regards the possibility of carrying out electronic scanning, it should then be noted that such a network only makes it possible to carry out electronic scanning in the plane perpendicular to the longitudinal axis of the waveguides which in practice is generally the plane of the electric field E at the outlet of this network.

 I1 is also known, in particular from French patent N "79 03272 to associate with such a network a device making it possible to carry out an electronic scanning along the plane of the magnetic field H at the output of this network, in order to obtain an active antenna. electronically scanned in two planes.

 This device, which performs the functions of an active lens, essentially consists of a system of networks of conductive wires placed parallel to the electric field E received by the lens, and which can be made at will either continuous or cut, by switches such as diodes supplied by the wires on which they are mounted. This active lens thus makes it possible to carry out an electronic scanning along a plane perpendicular to the networks of wires, that is to say, said wires being arranged parallel to the electric field E received by the lens, along the plane H of the magnetic field received by The lens.

 It is therefore found that this planar active lens H has by nature a role complementary to the planar active antenna E and that it is thus naturally led to associate them.

 The subject of the present invention, on the contrary, is the use of an active lens providing scanning along the plane E, in association with an active antenna with electronic scanning along a plane, in order to obtain an active antenna with electronic scanning along two planes. orthogonal.

 According to the invention, a two-dimensional array antenna, with transceiver modules distributed over the surface of the antenna, and with electronic scanning, of the type with radiating elements grouped according to guidance means each associated with a transceiver module, is essentially characterized in that it further comprises, disposed in front of this array, an active lens capable of creating an electronic scan in the plane E of the electric field which it receives, preceded or not by a polarization rotation grid depending on whether this network scans along the plane E of the electric field, or along the plane H of the magnetic field.

 Other objects and characteristics of the present invention will appear more clearly on reading the following description of exemplary embodiments, made in relation to the attached drawings in which: - Figure 1 is a side view of an active antenna with electronic scanning according to the invention; - Figure 2 is a diagram showing the association of a transceiver module and a group of radiating elements, according to another characteristic of the invention; - Figures 3 and 4 are diagrams relating to the formation of several simultaneous beams in reception, by means of an antenna according to the invention.

 In Figure 1 there is shown, side view, an active antenna whose radiating elements are, for example, arranged along waveguides such as li, horizontal, that is to say perpendicular to the plane of figure, and juxtaposed vertically so as to cover the entire surface of the antenna.

 This array antenna makes it possible to carry out an electronic scan in a plane orthogonal to the longitudinal axis of the guides, that is to say in the example considered in the vertical plane, this plane possibly being the plane E of the electric field or the plane H of the magnetic field.

 This array antenna is followed by an active lens 2 capable of carrying out an electronic scanning along the plane E of the electromagnetic wave which it receives. In the case where the array antenna also scans along the plane E, this active lens 2 is itself preceded by a grid 3 of polarization rotation. In the example considered, the electric field E at the output of the polarization rotation grid is then perpendicular to the plane of the figure.

 In the case where the array antenna scans along the plane H, the grid 3 for polarization rotation is not provided; this is why this grid has been shown in dotted lines.

 The assembly formed by elements 1 and 2, or 1, 2 and 3 depending on the case under consideration, therefore provides an electronic scan along two orthogonal planes.

 A description of an electronically scanned active lens according to the plane E will be found in particular in French patent N "79 27873.

This active lens works according to a principle analogous to that described in French patent n ° 79,03272, but allows, thanks to a cutting of the wires of the same network into several sections supplied in a separate manner, to find in a way the properties of phase shift of a system of arrays of wires arranged perpendicularly to the latter, and thus to perform, while still having wires arranged parallel to the electric field, an electronic scan no longer along the H plane but along the plane
E of the electric field received by the lens.

 The polarization rotation grid is also a conventional antenna device; it will not be described here.

 The active lens with scanning along the H plane used in French patent NO 79 03272 in association with an active antenna also makes it possible to compensate for the frequency dispersion due to the location of the various transceiver modules at the end of the guides. associated with each of these modules.

 According to another characteristic of the invention, this frequency dispersion is avoided thanks to a parallel distribution network 4i between each of the transmitter-receiver modules 5i and the different radiating elements 6. which are associated with it (j being an index which varies horizontally and i an index which varies vertically). This appears in FIG. 2 which is a view in a plane orthogonal to the plane of FIG. 1.

 These parallel distribution networks 4i in fact replace the previous waveguides li. The equality of the different possible paths inside these parallel distribution networks thus avoids the frequency dispersion phenomenon encountered previously with guides supplied at one of their ends.

 These parallel distribution networks can be produced in particular by means of lines of the "microstrip" or "triplate" type.

The number of successive divisions made within these networks depends on the width of the interval between two adjacent radiating elements.

In FIG. 2 also appears the constitution of the transceiver modules 5 Each of these modules comprises a transmission chain and a reception chain, each of which in turn comprising amplifiers (respectively 7 8 and 9, 10, 10.)
III amplitude adjustment devices (respectively 11. and 12.) and
II phase adjustment devices (respectively 13. and 14.).

ii
The emission channel has an input C. and an output Ei, the
II reception channel has an input Di and an output B ..

ii
Points D. and E. are alternately connected to the access point
I i
F. to the 4i parallel distribution network via a
ii switching device 15i.

Points B. and Ci are alternately connected, via the inter
ii medium of a switching member 16i, at the access point A. to a microwave distribution network possibly comprising the formation of monopulse channels or of preformed simultaneous beams.

 It is also possible to form, on reception, independent beams dynamically controlled by means of attenuators and phase shifters.

 Figure 3 gives an example of this possibility. The signal received in D is amplified, then divided, possibly after frequency change by means of a local oscillator OL, into a certain number of components (four in the example considered) each of which is independently controlled in amplitude (respectively by means amplitude control devices 12il, 12i2, 12i3 '12i4) and in phase (respectively by means of phase control devices 14il, 14i2, 14i3> 14i4) before feeding different networks (not shown in these figures ) beam formation from the different channels thus obtained in the different modules.

 Even more flexible is the formation of the beams by computer, shown in FIG. 4. For this, each module comprises a complete reception chain, that is to say comprising an amplitude-phase detector 17i controlled by a frequency reference signal REF.FI intermediate and providing the amplitude A and phase ç of the received signals. Amplitude A and phase <p are then converted to digital using an analog-to-digital converter 18i.

 A computer (not shown in this figure) can then process all the signals thus obtained in the different modules to form at will beams whose number, shape and orientation can change dynamically.

 Obviously, these simultaneous beams can only be formed in the scanning plane of the active antenna scanning along a plane. In the other scanning plane, that of the active lens, all the beams undergo the same deviation (expressed in sine of the angle).

Claims (4)

 1. Two-dimensional network antenna, with transmitter-receiver modules (5i) distributed over the surface of the antenna, and with electronic scanning, of the type with radiating elements (6.) grouped together according to guide means (li) each associated with a transmitter-receiver module , characterized in that it further comprises, disposed in front of this array, an active lens (2) capable of creating an electronic scan in the plane E of the electric field which it receives, preceded or not by a rotation grid of polarization (3) depending on whether this network scans in the E plane of the electric field or in the H plane of the magnetic field.  2. Antenna according to claim 1, characterized in that the active lens (2) capable of creating an electronic scan in the plane E of the electric field which it receives comprises juxtaposed assemblies of networks of conductive wires arranged parallel to the electric field E received, and which can be made continuous or discontinuous by switches such as diodes supplied by the wires on which they are mounted.  3. Antenna according to one of claims 1 and 2, characterized in that the guide means consist of networks (4i) with parallel distribution connecting by identical paths each transmitter-receiver module to the different radiating elements which are associated with it.  4. Antenna according to one of claims 1 to 3, characterized in that each transceiver module comprises several reception channels each comprising amplitude and phase control members, so as to form several independent beams from the different channels thus obtained in the different modules.