FR2949609A1 - Active reflectarray antenna, has radiation cells sending signal with phase shift, and piston formed by head that is positioned such that length between input of waveguide and head defines value of phase shift of sent signal - Google Patents

Abstract

The antenna has radiation cells for sending a signal with a phase shift, where the signal is transmitted in the form of a wave. Each cell includes a radiation element coupled to a waveguide (GO) transmitting the received wave, and a short-circuit device having a piston (PT) formed by a head (TE) to which an axle (AX) is fixed. The head slides the transmitted wave within the waveguide and reflects the transmitted wave to the radiation element. The head is positioned such that a length between an input of the waveguide and the head defines a value of the phase shift of the sent signal.

Description

An active network antenna of radiating cell type.

The present invention relates to active network antennas of the radiating cell type commonly known as active Reflectarray by those skilled in the art (active reflector network in the English language). This type of network antennas receives a signal radiated by an external electromagnetic source, the signal being transmitted in the form of a polarized wave. More specifically, a so-called active Reflectarray network antenna is formed of several cells arranged in a network on the same plane and illuminated by the external source. Conventionally, a cell comprises: a radiating element able to pick up the wave coming from the external electromagnetic source and to send it outwards after a given treatment, a waveguide able to transmit the wave from or to the radiating element, and a phase shift element capable of phase shifting the received wave before reflecting it to the radiating element. This phase shift element makes it possible to phase shift the wave received from the external source according to a controlled phase shift value in the case of an active grating antenna (a so-called electronic grating antenna is then obtained). The phase shifting elements also have the role of compensating the difference in length of the rays between the external electromagnetic source and each radiating element. A problem with this type of antenna is that it is poorly suited to high frequency signals, for which high power losses occur during the phase shift and reflection of the signal by the cells. In addition, the phase shift elements then used are particularly expensive. An object of the invention is in particular to solve the problems mentioned above. For this purpose, according to a first aspect of the invention, there is provided an active array antenna of the radiating cell type capable of returning a received signal with a phase shift, each radiating cell comprising: a radiating element coupled to a guide circular section wave adapted to transmit the received wave, and - a short circuit device. According to a general characteristic of this first aspect, the short-circuit device comprises a piston formed of a circular section head to which is fixed an axis, the head being able to slide within the waveguide and to reflect towards the element radiating the wave transmitted by said waveguide. Said head is positioned so that the length between the entrance of the waveguide and the piston head defines the value of said phase shift of the returned signal. In other words, a piston inserted within the waveguide makes it possible to vary the length of the waveguide, and thus to adjust the phase shift of the reflected wave. The short-circuit device according to the invention is particularly simple and makes it possible to reflect the wave with a minimum loss of power. According to one embodiment, each cell comprises a stop terminal fixed on a suitable support, outside the waveguide. The axis of each piston comprises two fixed disks, spaced a length I selected, and distributed on either side of said stop terminal, so that the piston is only able to slide the length I selected so to adopt two distinct positions. Preferably, a groove may be formed around the periphery of the piston head. According to one embodiment, the antenna may comprise a number n of rows of cells arranged on the same plane, n being an integer, the cells being arranged between them in a chosen mesh.

According to another aspect of the invention, it is proposed to use an antenna according to one of the preceding claims within a radar. Other advantages and features of the invention will become apparent upon consideration of the detailed description of non-limiting embodiments of the invention and the accompanying drawings in which: FIG. 1 illustrates a Reflectarray active type array antenna; FIG. 2 illustrates an exemplary arrangement of a network antenna according to the invention, FIG. 3 very schematically illustrates one embodiment of the invention; FIG. 4 illustrates an embodiment of a According to the invention, FIGS. 5 and 6 illustrate in greater detail one embodiment of the invention. FIGS. 7 and 8 illustrate by way of example the multi-polarization operating capacity of the network antenna. according to the invention. Referring to FIG. 1, the reference RA denotes a Reflectarray active type array antenna, viewed from above. This is illuminated by an external electromagnetic source SC. The source SC may for example have a monopulse type operation, that is to say send a signal slightly offset on one side of its optical axis 25 by rotating it about said axis. A more detailed definition of the source will be given below. The wavefront FOC of the radiated signal SIR by the source SC is here spherical (in other words, the identical phase surface of the radiated wave is spherical).

The energy of the SIR radiated signal is naturally distributed in the space between the SC source and the Reflectarray RA active network antenna. This antenna RA is formed of several CEL cells arranged here on the same plane. An exemplary arrangement of CEL cells is described in more detail below. Each CEL cell is formed of a radiating element ER connected to a waveguide GO, here of circular section maintained by a support SP. These symmetrical waveguides are particularly suitable for use within a radar. Within the GO waveguide is a short circuit device in the form of a PT piston. Thus, the wave radiated by the source SC propagates in free space and is picked up by each radiating element ER. It then propagates inside each GO waveguide until it encounters the PT piston acting as a short circuit. The piston PT reflects the wave transmitted by the waveguide GO. The reflected wave crosses the waveguide and is returned to the radiating element ER. Each radiating element ER then emits a SIRE signal with a phase shift function of the position of the piston PT within the waveguide GO as explained in more detail below. Note that the FOP wavefront of the signal SIRE is plane if the values of the phase shifts are correctly chosen. Figure 2 illustrates an exemplary cell distribution (front view) of a multi-row Reflectarray active type antenna. The distribution shown here follows a triangular mesh. Alternatively, the mesh could be rectangular. It is noted that the impedance matching of the opening of circular waveguides GO can be achieved by conventional means such as dielectric plugs inserted into the mouth of the waveguides, a dielectric panel positioned on the waveguide array ...) Referring now to FIG. 3 which more precisely illustrates the piston PT within the waveguide. The letter E denotes the entry of the waveguide of circular section GO, that is to say the end of the waveguide GO coupled to the radiating element ER.

This piston PT comprises a head TE (gray in the figure) to which is fixed an axis AX. The head TE is circular in section so as to perfectly match the internal contours of the GO waveguide.

The head TE of the piston PT may be for example made of aluminum or a metal covered with gold or silver.

The piston PT is able to slide within the waveguide. For example an electromagnetic device (such as an electromagnet) (not shown for simplifications) located outside the waveguide GO, can move the piston from one position to another.

In this example, we consider a GO waveguide of diameter D and radius a (D = 2 * a).

The signal received by the radiating element ER oscillates at a frequency F corresponding to a wavelength (typically of the order of a few millimeters), such that A0 = F, where c is the speed of light. Length I represents the distance between the opening E of the waveguide GO and the piston. More generally, in the rest of the text, the length I represents the distance between two successive positions of the head TE of the piston PT within the waveguide GO.

This length I is proportional to the phase shift made by each cell. More precisely, it comes: 25 çP_ 360x2x1 2g where:

cp is the value of the phase shift realized by a cell in degree, I is the length between two successive positions of the head TE of the piston PT within the waveguide GO, and / tg is the guided wavelength in a mode of given propagation, such that 2g =, where 2 is [i (2)] the cut-off wavelength, with for example 2 = 3.412 * a for the propagation mode called TE11 (described in more detail below) ), a being the radius of the waveguide considered.

For example, in the case of a 1-bit phase-shifted cell (that is, the cell can phase-shift the signal into two distinct phase values) comprising a circular waveguide with an equal diameter D at 3.4mm, if F = 77GHz, then the guided wavelength 2g is equal to 5.24mm and the displacement of the piston between the two positions corresponding to the two values of possible phase angle (here 0 and 180 ° ) is equal to 1.3mm. No electrical contact exists between the piston and the cylindrical GO waveguide. In order to prevent parasitic currents from propagating along the piston, a trap PG can be produced as illustrated in FIG. 4. This trap PG is here a narrow groove formed around the periphery of the head TE of the piston PT. A secondary axis AX connects the two parts of the head TE on both sides of the trap PG. The thickness e of this groove is small compared to the wavelength 2g and the depth is of the order of 25 2g / 4, where 2g is the value of the guided wavelength. Referring now to FIGS. 5 and 6 which further illustrate the embodiment of the piston PT of FIG.

In this embodiment, two disks D1 and D2 are attached to the axis AX of the piston PT. These disks D1 and D2 are spaced apart by a length b chosen. A fixed stop terminal PF is disposed on a support SP. In this example, the fixed stop terminal forms a T, the width c of the vertical portion of the T being less than the length b between the two disks D1 and D2. Thus, when the piston PT slides within the waveguide GO, the two disks D1 and D2 move respectively on either side of the fixed stop terminal PF. FIG. 5 represents the first position, that is to say when the piston has moved back from left to right and the first disk D1 is blocked by the fixed stop terminal PF. Fig. 6 shows the second position, i.e., when the piston PT has moved from right to left, and the second disk D2 is blocked by the stationary stop BAF. Between the two positions, the piston PT has moved a length b. The length I between the input of the waveguide GO and the surface of the head TE of the piston PT has therefore increased by length b. To illustrate the multi-polarization operating capacitance of the invention, FIG. 7 represents the electric field lines propagating within a waveguide GO having a circular section here of radius a, according to the invention. These field lines are polarized according to a dominant polarization mode known as TE11, well known to those skilled in the art. The lines 25 of fields here are predominantly vertical. These field lines result from the illumination of the GO waveguide by an external source operating in vertical linear polarization. FIG. 8 represents the electric field lines propagating within the same GO waveguide with circular section. The 30 field lines here are predominantly horizontal and show an angular rotation of + 90 ° with respect to the field lines of FIG. 7.

The field lines shown in FIG. 8 result from the illumination of the waveguide GO by an external source operating in horizontal linear polarization. An external source sensitive to the two orthogonal linear polarizations may excite (on transmission) or receive (on reception) both of the linear polarizations mentioned above. Note that the source term is used broadly, according to the conventional use that is made by the skilled person. In transmission, the source is used as an illumination device, and on reception, it functions as a capture probe. In other words, the operation of a source is here that of a conventional reflector (for example a parabola) used in transmission and reception. Thus, a source can excite or capture a combination of two orthogonal linear polarizations, in particular a circular polarization, which can be defined as the combination of two orthogonal linear polarizations in phase quadrature (+ 90 ° or -90 ° between the two linear components of the same amplitude). The behavior of the waveguide (ie its impact on the length of the guided wave) and the operation of the piston remain the same.

The operation of the Reflectarray active type network antenna according to multiple polarizations (linear, circular, elliptical) is thus obtained simply with a single source sensitive to the different polarizations considered. In the case of antennas having a conventional architecture of the active Reflectarray type, made either from phase shift cells of the bi-polarization type, or from an interlacing of phase shift cells operating in two orthogonal polarizations, the phase shift cells have of a phase shift element for each of possible polarizations. The invention therefore has a certain advantage in terms of compactness, cost and simplicity of operation.

It should be noted that this source can be produced conventionally in the form of a single radiating element or a small directional network, or in printed technology (patch with two accesses, possibly equipped with a hybrid coupler) or else in technology based on waveguides (for example a multi-polarization horn, possibly equipped with a hybrid coupler).

Thus, the invention is particularly suitable for multi-polarization operation (without modification of the short-circuit device), which is commonly used or in radars.

Claims (4)

REVENDICATIONS1. An active network antenna (RA) of radiating cell type (CEL) capable of returning a received signal with a phase shift, each radiating cell (CEL) comprising: - a radiating element (ER) coupled to a waveguide (GO) at circular section adapted to transmit the received wave, and - a short-circuit device, characterized in that the short-circuit device comprises a piston (PT) formed of a circular section head (TE) to which is fixed an axis (AX), the head being able to slide within the waveguide (GO) and to reflect towards the radiating element (ER) the wave transmitted by said waveguide (GO), said head (TE) being positioned so that the length between the inlet of the waveguide and the head (TE) of the piston (PT) defines the value of said phase shift of the returned signal. 2. An array antenna according to claim 1, wherein each cell (CEL) comprises a stop terminal (PF) fixed on a suitable support (SP) outside the waveguide (GO), and in which the axis of each piston comprises two fixed disks (D1, D2), spaced apart by a length I chosen, and distributed on either side of said stop terminal (PF), so that the piston (PT) is only adapted to slide the chosen length I to adopt two distinct positions. 3. Antenna according to one of the preceding claims, wherein a groove (PG) is formed on the periphery of the head (TE) of the piston (PT). 4. Antenna according to one of the preceding claims, comprising a number n rows of cells (CEL) arranged on the same plane, n being an integer, the cells being arranged between them in a selected mesh. . Use of an antenna according to one of the preceding claims within a radar.