EP2559102A1

EP2559102A1 - Wideband, directional, linearly polarized antenna having high polarization purity

Info

Publication number: EP2559102A1
Application number: EP11715189A
Authority: EP
Inventors: Michel Jousset; Gaetan Guevel; Gaelle Samson
Original assignee: Thales SA
Current assignee: Thales SA
Priority date: 2010-04-13
Filing date: 2011-04-07
Publication date: 2013-02-20
Anticipated expiration: 2031-04-07
Also published as: FR2958804A1; ES2450125T3; EP2559102B1; US8976073B2; WO2011128243A1; FR2958804B1; US20130207864A1

Abstract

In the field of wideband directional antennas operating in linear polarization, and in particular in the framework of amplitude goniometry systems, polarization purity defects result in deformation of the radiation patterns and cause the localization performance of the detection system to deteriorate. The antenna of the present invention is an antenna operating in linear polarization and having sinuous radiating elements inscribed within a circle, and comprises radiating elements printed on both surfaces of a substrate, the elements of a first surface being derived from those of the other surface by rotation.

Description

RECTIFIED, DIRECTIVE, BROADBAND POLARIZED ANTENNA WITH HIGH POLARIZATION PURITY

The present invention relates to a linear polarization antenna, directive, broadband, high polarization purity.

In the field of broadband directional antennas operating in rectilinear polarization, and in particular in the context of amplitude direction finding systems, it is generally found, with antennas of this type, a degradation of the accuracy of the measurement of the DOA ( "Direction of arrivai" or direction of arrival in French) of targets. In this case, polarization purity defects cause a deformation of the radiation patterns (phenomenon called "squinting") which increases with the site, inducing a degradation of the localization performance of the detection system.

This problem is currently solved using non-generalizable empirical solutions, such as, for example, the addition of wire networks in front of the antenna.

The subject of the present invention is a high-purity polarization antenna (a frequency band that may be greater than the decade) of the printed circuit type, this antenna being able to be integrated into a bi-polarization antenna, and allowing, when it is used in a localization system, to improve the localization performance, particularly at non-zero sites.

In the case where this antenna is of the rectilinear polarization type, its theoretical co-polarization is defined with respect to the geometry of the radiating circuit. In practice, real co-polarization differs from theoretical co-polarization. Polarization purity is defined as the difference between the theoretical polarization and the real co-polarization. It can be measured using the "co-polarization level / cross polarization level" ratio in the geometrical definition plane of the antenna. If the antenna is perfect, this ratio is infinite. In practice, what we are looking for is a ratio generally between 15 dB (for a log-periodic antenna) and 20 dB (for a "sinuous" antenna). The antenna according to the invention, of the plane support type is a linear polarization antenna, directive, broadband and high purity polarization, at least one pair of radiating elements printed on a face of a circuit printed, the two elements being symmetrical to each other with respect to the center of the antenna and delimited in their angular extension by two virtual lines passing through the center of the antenna, and it is characterized in that it has radiating elements printed on the other side of the support, these elements being identical to those of the first face, and being deduced by a rotation of 180 ° about an axis passing through the center of the antenna and which is the bisector of the angle at the center of said pair of elements, this central angle being that formed by said two virtual lines, this rotation being followed by a translation over a distance equal to the thickness of the printed circuit.

The present invention will be better understood on reading the detailed description of an embodiment, taken by way of nonlimiting example and illustrated by the appended drawing, in which:

Figure 1 is a plan view of an antenna of the prior art, and Figure 2 is a plan view of an antenna according to the present invention.

The present invention is described below with reference to an antenna operating in rectilinear polarization and "sinuous" radiating elements inscribed in a circle, but it is understood that it is not limited to such a type of antenna. antenna, and that it applies to any antenna with linear radiating elements, radiating in linear polarization, wired geometry, which one seeks to improve the purity of polarization, antenna whose co-polarization is supposed to be rectilinear, broad band or no, which can, if necessary, be the basic element for the design of a bipolarization antenna.

The antenna type from which the invention is derived is generally that realized using a single-sided printed circuit manufacturing technology. An example of such an antenna 1 of the prior art is shown in Figure 1. It comprises essentially two radiating elements or sinuous branches 2, 3 symmetrical to each other with respect to the geometric center O of the assembly. It is well heard that this antenna could include two other branches. The layout of the radiating elements of a so-called "sinuous" antenna is well known, for example according to US Pat. No. 4,658,262, it will not be described in more detail here. It will be specified only here that the two arms 2, 3 are symmetrical to one another with respect to the center 0. These two arms are delimited in their angular extension a by two virtual lines A, B passing through the center O of the 'antenna.

The antenna 4 of the invention, as shown in FIG. 2, is of the double-sided printed circuit type. Figure 2 has been shown as if the printed circuit on which the radiating elements are formed was transparent. The first face, which is assumed to be the anterior face, has the same branches 2, 3 as those of FIG. 1. The posterior face of the printed circuit comprises the branches 4,5, whose shapes and dimensions are identical to those of FIGS. branches 2, 3.

According to the view of FIG. 2, the location of the branches 4, 5 is deduced from that of the branches 2, 3 by rotation of 180 ° about an axis C passing through the center O and which is the bisector of the angle in the center has branches 2, 3. In reality, it would be necessary to add to this rotation a translation over a distance equal to the thickness of the printed circuit (from the anterior face to the rear face of this printed circuit).

In other words, the outline of the branches 4, 5 is obtained by rotation of the branches 2, 3 around the center O by an angle of value equal to (180 ° +), then by the same translation. In the case of a four-branched antenna (two pairs of branches), only one of the pairs is considered for rotation.

The invention makes it possible to improve the polarization purity of the antenna by more than 10 dB relative to the geometry on a single-sided printed substrate. More generally, it makes it possible to obtain an improvement in the polarization purity of all the geometries of planar wire antennas (log-periodic and other type antennas). Applied to bipolarisation antennas, it improves the coupling between the two radiating elements.

Claims

1. Antenna of the linear polarization, directive, broadband and high purity polarization plane support type, to at least one pair of radiating elements (2, 3) printed on one side of a printed circuit, both elements being symmetrical to each other with respect to the center of the antenna (O) and delimited in their angular extension by two virtual lines (ΟΑ, ΟΒ) passing through the center of the antenna, characterized in that it comprises radiating elements (4, 5) printed on the other face of the support, these elements being identical to those of the first face, and deduced therefrom by a rotation of 180 ° about a passing axis (OC) by the center of the antenna and which is the bisector of the angle at the center (a) of said pair of elements, this central angle being that formed by said two virtual lines (OA, OB), this rotation being followed a translation over a distance equal to the thickness of the printed circuit.

2. Antenna according to one of the preceding claims, characterized in that each face of the printed circuit comprises two sinuous-shaped arms.

3 Antenna according to one of claims 1 or 2, characterized in that each face of the printed circuit comprises two arms log-periodic form.

4. Antenna according to claim 1, characterized in that it is a rectilinear bipolarization antenna.