FR2890791A1 - Electronically-scanned antenna e.g. radar antenna, has phase-shifters coupled to two branches of radiant sources supplied by primary source emitting arbitrary polarization electromagnetic waves and/or receiving multiple polarization waves - Google Patents

Abstract

The antenna has a primary source, formed by a horn (1), supplying a network of radiant sources (10) each with two radiant slits containing branches (11-14) in cross polarization. An electronically controlled reciprocal phase-shifter (5) is connected to the branches (12, 14) for each source. The primary source emits electromagnetic waves with arbitrary polarization and/or receives waves with multiple polarization.

Description

ELECTRONIC SCAN ANTENNA

  ARBITRARY OR MULTIPLE POLARIZATION

  The present invention relates to arbitrary or multiple polarization electron scanned antennas.

  When emitting an electromagnetic wave, it is generally decided to transmit the wave according to the polarization that is most favorable to the detection as a function of the type of target sought and the meteorological conditions. For example, circular polarization waves are emitted to avoid being generated by drops of water, because the circularly polarized waves are reversed by reflecting on the drops of water.

  On reception, the choice of polarization can be based on the criterion of the strongest useful signal or the weakest parasitic signal. One will choose for example to receive in a polarization orthogonal to that which can emit a jammer. It is therefore necessary to have the two components of the polarization either on transmission or on reception.

  In some applications the two polarization components make it possible to use a coding on transmission which makes it possible to recognize the reception of the shape of the target after the treatment of the two components. Indeed, if one emits a sequence of circular polarization right and left following a binary code, the target returns the signal with the same code of polarization if it is a tense or with an inverted code if the target is spherical or has a surface of revolution.

  In the case of antennas consisting of an assembly formed by a primary source and a focusser (generally one or more centered or non-centered reflectors, or a lens), the polarization of the assembly is that which is given by the primary source.

  In order to obtain an arbitrary or multiple polarization in this case, for example, two crossed dipoles placed in front of a reflector or a symmetrical horn having two cross polarization excitation ports are used as primary source. An arbitrary polarization is obtained by feeding both accesses via a polarizer and an attenuator. A multiple polarization can be exploited at the reception by having a receiver for each access.

  In the case of electronic scanning antennas, phased array antennas are used. In order to obtain an arbitrary polarization, it is necessary to equip each source of the network with elements such as crossed dipoles or symmetrical horns, therefore having two accesses each controlled by a phase-shifter and an attenuator for each element to regulate. the amplitude and phase of the signal. In addition to receiving multi-polarized signals it is necessary to double the entire network of power supply circuits and phase shifters to achieve two separate receivers.

  However, the cost of such an electronic scanning antenna is proportional to the number of phase shifters, this number being multiplied by two in this case. The realization of such an antenna is therefore more complex and more expensive.

  The present invention overcomes these problems. It consists in using an arbitrary or multiple polarization primary source illuminating a reflector network constituted by phased sources.

  The subject of the invention is an arbitrary or multiple polarization electron-scanning antenna that does not need to double the equipment and in particular the phase-shifters, on the one hand because the amplitude and polarization phase laws are given by the primary source which illuminates the reflector array and secondly because the phase shifters are connected to the radiating elements of each source of the grating as explained below so that these elements can emit and / or receive multi-polarized waves. or arbitrary.

  The present invention therefore relates to an arbitrary or multiple polarization electron scanning antenna comprising a primary source for supplying an array of reflective sources constituted by two radiating elements in cross polarization and a reciprocal phase shifter associated with each source, characterized in that that the primary source is capable of transmitting waves of arbitrary polarization and / or of receiving waves of multiple polarization, and that the phase shifters allow the two radiating elements of each source to be connected together.

  Other features and advantages of the present invention will emerge from the following description, illustrated by the accompanying drawings or: FIG. 1 represents an embodiment of the antenna according to the invention; FIG. 2 represents an embodiment of a radiating element of the network according to the invention; FIG. 3 represents a sectional view of an embodiment of the network relating to a particular technology, according to the invention; FIG. 4 shows an alternative embodiment of a radiating element according to FIG. 2; - Figure 5 shows another embodiment of radiating element according to the invention.

  FIG. 1 shows an electronic scanning antenna according to the invention. The antenna comprises a primary source 1 capable of transmitting wave polarized in any manner and variable to the emission and capable of receiving receive simultaneously two orthogonal components of the incident polarization: for example vertical and horizontal. The primary source is classic in itself. It can be performed by a horn as shown in this FIG. 1 equipped to radiate waves according to a multiple or arbitrary polarization, according to a predetermined phase law and amplitude. The transmitter 3 radiates a wave divided into two parts by means of a variable divider 4. One of the partial waves is out of phase with the phase-shifter 5, the other can be attenuated with the attenuator 6. These two waves excite, by means of circulators 7, 8 (playing the role of duplexers) both accesses. cross-polarization of the horn 9. An arbitrary transmitted polarization is thus obtained. On reception, the signals received in the two components (horizontal u> and vertical v'3 are transmitted through the circulators 7, 8 to two Ru receivers Rv (possibly equipped with protection limiters) for operation.

  The antenna also comprises a phased array 2. This array is a reflector array comprising a set of radiating sources 10. Each source has two cross-polarized accesses in order to be able to transmit or receive waves with multiple or arbitrary polarization.

  Each source consists of two elements capable of radiating part of the energy emitted by the primary source, the primary source constituting the supply.

  In this figure the sources of the network are each constituted by two crossed radiating slots having two branches 11, 12 and 13, 14. An electronically controlled phase shifter 15 connects two orthogonal branches 12, 14 of the two slots for each source.

  Each phase-shifter is controlled, in a conventional manner, to phase-shift the waves emitted by each source so as to compensate the phase delay due to the propagation from the primary source and to print to the grating the phase gradient producing the orientation of the beam.

  Each phase shifter therefore connects two orthogonal branches so that the energy received by one slot passes through the phase shifter and is re-irradiated by the other slot in the case where the waves are polarized in a single vertical or horizontal direction. that is to say in the direction of one of the elements constituting each source.

  In the case where the waves have a polarization other than one of these two directions (vertical or horizontal), a fraction of energy (for example the horizontal component) is picked up by one branch, the other fraction (for example the vertical component) is picked up by the other branch. Thus the energy picked up by a vertical branch passes into the phase-shifter and is re-radiated by the horizon-tale branch, and conversely the energy captured by a horizontal branch passes into the phase-shifter and is re-radiated by the vertical branch. There is an exchange between the radiation of the vertical and horizontal branches.

  Indeed, any polarization can be represented by a column matrix of two complex numbers (a, b) or, more conveniently, by a complex vector having these two numbers (a, b) for components according to a given referential. By choosing as a frame of reference (iu, v a trihedron formed of three orthogonal unit vectors defining the direction of the radiation, u the horizontal component and v> the vertical component, a polarized wave pi can be written p 1 = at + bv, (a, b) corresponding to the law of amplitude and phase given by the primary source.

  For a horizontal polarization pi = a û; for a vertical polarization p1 = b v>; for a right circular polarization pi a + i v>), (i = f 1); for left circular polarization>> p1 = a (u-iv).

  A primary wave i emitted by the vertical polarization primary source, gives a secondary wave p2 radiated by the horizontally polarized array. Reciprocally, a horizontal polarized primary wave gives a vertically polarized secondary wave. Any polarization wave which can always be vertically decomposed into a horizontal and vertical component undergoes a symmetrical transformation between its components; the secondary wave p2 results from an exchange between the horizontal and vertical component of the primary wave p1 'Indeed, if pi is the polarization of the primary wave incident on one of the elements of the network, the coefficients a and b which define it are under the dependence of the primary source exclusively, the secondary wave p2 is obtained simply by permuting the horizontal and vertical components. There is therefore a symmetry with respect to the main diagonal. As a result of reflection (which is the case of normal incidence) the wave changes direction. We then refer to a modified referential so that it remains a direct trihedron, ie (e W) this trihedron with: û = - d v '= vn? = - n> The emerging secondary wave that can be written p2> av + bu> is written according to this direct trihedron 2> -b ui + a This emergent wave is always under the control of the primary source.

  Each phase-shifter has a function additional to the usual function, since it also makes it possible to perform an orthogonal linear transformation on the polarization of the wave.

  Some examples are given as an indication in the table below: Primary polarization pl Secondary polarization p2 horizontal p 1 = to 'vertical p2' = vertical av pl> bv 'horizontal p2 - circular bu pl = a (u + iv circular of the same direction : diagonal pl = a (u + v ') p2> - is (u' + iv?) diagonal parallel P2-a (-ci- v ') The operation on reception is reciprocal The wave analyzed by the primary source has a polarization symmetrical to that of the incident wave coming from the network.

  In Figure 2, there is shown a particular embodiment of radiating element.

  The reflector network is flat for example. Each bipolarization element 10 is formed of two crossed slots 11, 12 and 13, 14. These slots are made on a metallized metallic support 23 or metal, the chosen technology depending on the power that must have the antenna. The two accesses A and B in cross polarization are interconnected by the phase shifter 15 by means of a supply line for each radiating element. This line comprises two sections 21 and 22.

  The feed points A and B are placed on the slots so that a correct impedance match is obtained: these points A and B are not necessarily in the center of the slots but they are chosen to obtain a better adaptation. The ends 17 of the slots can be expanded in a T-shape according to this example, which can improve the adaptation especially in the case of a wide frequency band.

  FIG. 3 shows an example of a planar network seen in section.

  The grating is made on a printed circuit comprising the double-sided metallic substrate (substrate). This support is thus covered with a metallization 23 in which are traced the slots 15 (no metallization). On the other side of the support are placed the feed line sections 21, 22 for each slot. These sections are made by metallization strips on the support 20 (microstrip type). At the rear of the printed circuit is a reflector plane constituted for example by a metal plate 24.

  Figure 4 shows another embodiment of radiating element. The element is also in the form of two crossed slots 11, 12, 13, 14 whose ends 18 have a flared shape. This extension of the slots also makes it possible to perform the impedance matching for the power supply lines of the phase-shifter.

  In Figure 5 there is shown another example of radiating element for the realization of the network. These elements are constituted by crossed dipoles 30, 31 - 32, 33 placed in front of a common reflector 40 located about a quarter wave behind the dipoles. Cross-polarized access A, B are connected to a coaxial line-type power supply line consisting of the two sections 21 and 22 connected to the phase-shifter 15.

  All microwave technologies can be used while remaining within the scope of the present invention in particular those which have been mentioned (strip or microstrip lines, coaxial lines) but also the air or dielectric triplic lines). Similarly any type of dual polarized antenna can be used while remaining within the scope of this invention.

  Other embodiments may be envisaged for the network including networks whose radiating elements have branches oblique to the alignment axes of this network.

  Similarly, one can use any kind of primary source for transmitting multiple polarization and receive independently and simultaneously two orthogonal polarization components (linear or inverse circular for example).

  Phase shifters are classic reciprocal phase shifters in themselves. These phase shifters are made by PIN diodes or ferrites. The fact that the phase shifters are reciprocal allows, of course, to apply the same phase shift in one direction of propagation as in the other.

  The invention therefore consists of an electronic scanning antenna comprising a primary source with arbitrary or multiple polarization, illuminating a network consisting of reflective sources. The reflective sources include radiating elements in cross polarization. The phase shifters are placed so as to connect two radiating elements of each source. This configuration makes it possible to halve the equipment necessary for producing a scanning antenna capable of emitting waves according to an arbitrary polarization or of receiving waves with multiple polarization.

Claims (8)

  An arbitrary or multiple polarization scanning electron antenna comprising a primary source for supplying a network of reflective sources (10) consisting of two cross-polarizing radiating elements (II, 12-13, 14) and a reciprocal phase shifter associated with each source, characterized in that the primary source is capable of transmitting waves of arbitrary polarization and / or receiving waves of multiple polarization and that the phase shifters (15) make it possible to connect the two radiating elements (11, 13 ) from each source.   2. Antenna according to claim 1, characterized in that the phase shifters (15) are electronically controlled phase shifters.   3. Antenna according to claim 1, characterized in that the elements (11, 12 - 13, 14) of the network are constituted by two slots (11, 12), (13, 14) crossed, the phase shifters (15) connecting a branch from one slot to another branch of the other slot.   4. Antenna according to claim 1, characterized in that the elements are formed by two crossed dipoles (30, 31 - 32, 33), the phase shifters (15) connecting a branch of a dipole to another branch of the other dipole.   5. Antenna according to claim 1, characterized in that the network is a plane array made on a printed circuit, one side of the circuit being partially metallized the non-metallized areas corresponding to crossed slots, the other side of the circuit having lines (21, 22) microstrip connecting the cross polarization accesses of two branches (12, 14), and in that a reflective plane (24) is placed at the rear of the printed circuit.   6. Antenna according to claim 1, characterized in that the network comprises a set of dipoles (30, 31 - 32, 33), supply lines (21, 22) connecting the accesses in cross polarization these two branches (33 , 31) of each dipole, and in that a reflector plane (40) is placed behind the dipoles, the phase shifter (15) being placed behind this plane (40).   7. Antenna according to any one of claims 1 to 6, characterized in that the primary source comprises a horn (1) having two cross-polarized access.   8. Antenna according to claim 7, characterized in that the cross-polarized accesses are respectively connected to an inlet of a circulator (7, 8), one of the circulators is connected to a phase-shifter (5), the other at an attenuator (6), the attenuator and the oscillator are connected to a transmitter (3) via a divider (4), the other input of each circulator being connected to the receivers (Ru, Rv) .