FR2958086A1 - Radiating element i.e. multi-layered microstrip patch, for e.g. single pole electronic scanning antenna array, has plate whose points are respectively connected to source and grounded for obtaining radiation, in one position of switch - Google Patents

Abstract

The element i.e. multi-layered microstrip patch (PMS), has a logical transfer switch (COM) connected to a plate having two excitation points (TR1, TR2), and attaining two positions. One of the points is connected to a microwave frequency generator source (S) via a power supply line and the other point is grounded via another power supply line having adjusted length to form an open circuit at the level of the latter point, for obtaining radiation in a complementary radiating zone, in one of the positions. The plate has a rectangular shaped copper antenna element engraved on a substrate layer.

Description

RADIANT ELEMENT OF EXTENDED ANGULAR COVERAGE OF DOUBLE MODE PAVE TYPE, USEABLE IN NETWORK

The invention relates to a radiating element or an antenna of the dual-mode block type with extended coverage that can be used in particular in a network, excited by a probe or metallized hole in the case of an antenna printed through the ground plane. The padded antenna according to the invention operates, for example, in the frequency range varying from a few hundred MHz to a few tens of GHz, from 10 MHz to 10 GHz, for example. The name "pad" (or "patch" or "patch" in English) is commonly used by the skilled person for antennas comprising a micro-tape pad printed on the surface of a dielectric substrate, at a distance a metal plane called "ground plane" classically etched on the other side of the substrate. These antennas are thin. The printed pattern is most often rectangular or low elliptical.

The design of an antenna radiating over an extended angular coverage, in particular a scanning array antenna, is hampered by the fact that the radiating elements constituting this grating themselves have limited angular coverage. A typical hard-to-achieve need is that of a scanning electron network antenna covering a hemisphere with correct radio characteristics (gain, lobes). FIG. 1 describes a microstrip type antenna illustrated in the French application of Applicant FR 09 01644. The antenna comprises a single layer of dielectric substrate SUB having a face on which is printed a microstrip type pad 30 PMS, and on the other side is printed with a mass plan PM. The antenna has an IC conical angular coverage over ± 60 ° about its axis AI, and an antenna consisting of a horizontal plane array of such microstrip pads typically provides coverage in electronic scanning on ± 01 ± 60 ° centered on the zenith. TR corresponds to the excitation point, in this example a metallized hole OM, made within the substrate SUB, so as to bring a current on the micro-tape PMS. FIG. 2 schematizes a "quarter-wave" monopole antenna above a ground plane that typically has a lateral angular coverage C2 about 40 °, and an antenna constituted by a horizontal plane network of such monopoles MV verticals over a ~ o ground plane typically ensures coverage in restricted electronic scanning about 02 = 40 ° to the horizon. A curved or 'V' type dipole antenna has a wider angular coverage, but with a gain reduction on the one hand towards the zenith, on the other hand towards the horizon. A non-planar antenna (cylindrical, spherical, made from facets) consisting of a network of microstrip blocks or dipoles makes it possible to provide angular coverage in a wider electronic scanning, to the detriment of the bulk, and requires a "(Turn off") the elements not participating in the radiation in the intended direction, so as not to disturb the radiation pattern It is possible to join two complementary network antennas, each dedicated to a beam pointing area, or even consider an antenna consisting of an interlacing of radiating elements used for radiation towards the zenith, and of radiating elements used for the radiation towards the horizon, in spite of all the advantages presented by the subject of the present invention, the latter have the following drawbacks in particular: • the 'conventional' radiating elements (blocks, monopoles, dipoles, etc.) do not have a co angular aperture sufficient, and thus do not allow in network to obtain an electronic scanning of the beam over an extended angular range (hemisphere) for example, • the curved dipole-type radiating elements have a wider angular coverage, but present a share of a gain fall towards the horizon and the zenith, and on the other hand present in network a strong variation of the impedance with the angle of pointing, requiring complex systems of adaptation of impedance, • the antennas non-planar networks present a large bulk, the overall number of channels is important, and in electronic scanning network, it is necessary to manage the extinction of sources not participating in the radiation in the intended direction, • the concept of contiguous antennas has a large footprint, • the concept of interleaving radiating elements is limited on the one hand by the physical dimensions of the pairs of ele In other words, it is necessary to avoid masking or disrupting the radiation of one network of elements by the other network.

The invention relates to a microstrip pad-like radiating element comprising at least one substrate layer SUB and a ground plane PM characterized in that it comprises at least: two modes of radiation obtained by first mode logic switching to a second mode and vice versa, said radiation modes corresponding to a division of the hemisphere radiated into a plurality of complementary zones, a first zone being represented by a cone CI of substantially vertical axis and a second zone by a cone C2 of substantially horizontal axis, and in that it comprises at least • a logic switch COM connected to a plate D, PMS disposed above the ground plane PM, • said PMS plate comprising a first excitation point TRI and a 30 second excitation point TR2, the first excitation point TRI being eccentric and connected to the logic switch COM by a line

LI power supply, the second excitation point TR2 being centered at the PM plate and connected to the switch by a line L2, • said COM switch comprising a first position for which the excitation point TR2 is connected to the ground M and the eccentric point TRI is connected via a coaxial or supply line LI to the source S microwave generator, length adjusted to perform a short circuit at the point TR2, to obtain radiation in the first zone of radiation, • said COM switch comprising a second position for ~ o which the point TR2 is connected by means of the line L2 to the microwave generating source S and the point TRI is grounded via the line LI of length adjusted to make an open circuit at the excitation point TRI to obtain radiation in the second radiation zone 15 complementary to the first. In the first position of the switch, the antennal element radiates in microstrip mode, that is to say in a vertical direction and in a cone of opening +/- 60 ° and in the second position of the switch, the antennal element, the radiation is horizontal over an angular coverage of the order of 40 to 60 °. The PM plate comprises, for example, on one of its faces a copper antenna element engraved on the substrate, of rectangular shape and / or low elliptical shape. The tile is for example a multi-layer technology pad. The radiating element according to the invention is, for example, used in electronic scanning antenna arrays, and / or in a frequency range varying from 10 MHz to 10 GHz.

Other characteristics and advantages of the device according to the invention will appear better on reading the description which follows of a

exemplary embodiment given by way of illustration and not limited to the appended figures which represent: • Figure 1 schematically illustrates a microstrip type antenna, • Figure 2, a quarter-wave monopole antenna on a ground plane, • FIG. 3, an example of a monopole antenna loaded by a plate, on a ground plane, FIG. 4, an example of a dual mode antenna according to the invention, FIG. 5, an illustration of the antenna. in operation according to the microstrip pad mode according to the invention, and • FIG. 6, an illustration of the antenna in operation according to the monopole mode according to the invention.

The idea of the present invention is based in particular on a specific use of the geometry of a radiation element and therefore its mode of operation. Thus, the proposed solution is to change by switching the geometry of this radiating element to make it radiate either towards the zenith or the horizon.

Figure 3 shows a radiating element that radiates like a monopole. The monopole geometry chosen here is that of a monopole loaded by a plate, also known under the abbreviation Anglo-Saxon `toploaded monopole 'or` capacitor plate monopole'. This concept is known to obtain an operation on a reduced height h (generally lower than that of the monopole `quarter of wave 'of height A / 4, see figure 2, where A is the wavelength corresponding to the frequency of antenna work) and to optimize the current distribution on the monopole strand. FIG. 3 shows an example of a monopole on a ground plane, PM charged by a disk-shaped plate D in this example and powered by the AM core of a coaxial CO passing in the center of the plate. The coaxial passes through the metallized hole TR made within the substrate SUB.

The plate may be circular, or square or take any geometric shape to obtain a monopole type operation. The plate may be a metal plate in the case where the working range corresponds to low frequencies. For operations of the antenna in higher frequency ranges, some GHz, the radiating elements are, for example, made by etching on a plate or dielectric substrate by means of copper, the radiating element being able to take the form of a square , 10 of disc, etc. FIG. 4 schematizes the arrangement of a microstrip-ribbon keypad which, by means of transfer switching detailed in FIGS. 5 and 6, will offer operation in monopole mode or microstrip mode mode, thanks to the presence of the PL plate and a logical transfer switch COM. For microstrip mode operation, the center of the keypad corresponds to a zero impedance point and can be connected to ground. In this configuration, the substrate has a first metallized hole OM1 and a second metallized hole OM2, passing through the SUB substrate and the ground plane through the OMS and OM2 ports and connected, respectively, by a CO coaxial and an AM core to the logic switch. COM transfer. The radiating element comprises two modes of radiation obtained by logic switching from a first mode to a second mode and vice versa, said radiation modes corresponding to a division of the hemisphere radiated into a plurality of complementary zones, a first zone being represented by a cone CI of axis AI substantially vertical and a second zone by a cone C2 of substantially horizontal axis A2. The axes substantially correspond to the axes specified in FIGS. 1 and 2. FIG. 5 schematizes an operating state of the antenna according to the invention for the microstrip pad mode. The COM switch is

connected to a microwave source S. The position of the logic switch is such that the central excitation point TR2 at the plate PMS is connected to the mass M via the hole OM2 and a line L2, while the excitation point TRI eccentric is connected via a coaxial or supply line LI to the source S microwave generator, length adjusted to achieve a short circuit at the point TR2. In this configuration, the antenna radiates in microstrip mode, that is to say in a vertical direction and in a cone of half opening 60 °.

For an attack at 500, this excitation point is positioned between the center of the keypad (zero impedance point) and the edge of the keypad (highest impedance). Figure 6 shows the operation of the antenna in a monopole operating mode. In this case the excitation point TR2 is connected by means of the line L2 to the microwave generating source S and the point TRI is grounded via the line L, of length adjusted to produce an open circuit at TRI excitation point level. In this mode of operation, the radiation is horizontal over an angular coverage of the order of 40 to 60 °.

The transfer logic switch COM is connected to a control and management device G of a radar or a telecommunications system according to the desired use, whose particular function is to control the position of the switch thus enabling the operation of stripe pad mode in monopole mode.

This configuration makes it possible to obtain, by electronic scanning, for example, a beam pointing upwards or a sweep towards the horizon.

The antenna according to the invention makes it possible, from the reconfiguration of the excitation of the keypad, to modify its mode of operation, and hence its radiation pattern, thus the distribution in space of the field radiated by the antenna. It is characterized, for example, by the use of a single radiating element to radiate either towards the zenith or towards the horizon The radiating element designed according to the invention can be used alone or in a network. Such an element is usable in network, in particular with electronic scanning, and allows the radiated beam to scan the hemisphere while maintaining good characteristics (gain, lobes), the hemisphere being described in two sections (towards the zenith, towards the horizon) characterized by a mode of radiation distinct from the constituent elements. 10

Claims (1)

CLAIMS1 - microstrip pad type radiating element comprising at least one substrate layer SUB and a ground plane PM characterized in that it comprises at least two modes of radiation obtained by logic switching from a first mode to a second mode and reciprocally, said radiation modes corresponding to a division of the hemisphere radiated into a plurality of complementary zones, a first zone 10 being represented by a cone CI of axis AI substantially vertical and a second zone by a cone C2 of axis A2 substantially horizontal, and in that it comprises at least: • a logic switch COM connected to a plate D, PMS disposed above the ground plane PM, • said PMS plate comprising a first excitation point TR1 and a second excitation point TR2, the first excitation point TRI being eccentric and connected to the logic switch COM by a supply line LI, the second excitation point TR2 being central at the PM plate and connected to the switch by a line L2, said COM switch comprising a first position for which the excitation point TR2 is connected to the ground M and the eccentric point TR1 is connected via a coaxial or supply line LI at source S microwave generator, length adjusted to make a short circuit at point TR2, to obtain radiation 25 in the first radiation zone, • said COM switch comprising a second position for which the point TR2 is connected by means of the line L2 to the microwave generating source S and the point TR1 is grounded via the line LI of adjusted length to make an open circuit at the point of TRI excitation to obtain radiation in the second radiation zone complementary to the first. 2 - radiating element according to claim 1 characterized in that in the first position of the switch, the antennal element radiates microstrip mode mode, that is to say in a vertical direction and in a cone half opening ± 60 ° and in the second position of the switch, the antennal element, the radiation is horizontal over an angular coverage of the order of 40 to 60. ° 3 - antenna element according to claim 1 characterized in that said PM plate comprises on one of its faces an antenna element made of copper engraved on the substrate, of rectangular shape and / or low elliptical shape. 4. An antenna element according to claim 1 characterized in that the block is a multi-layer block. 5. Use of the radiating element according to one of the preceding claims in electronic scanning antenna arrays. The use of the radiator according to claim 1 in a frequency range of 10 MHz to 10 GHz. 2515