FR2686193A1 - HIGH GAIN DIRECTIVE ANTENNA WITH RADIANT PART SUPPORTING HEAT. - Google Patents

Abstract

The radiating part (4) comprises a solid monopolar element, comprising a foot (17) of low height fixed to the ground plane (9) and a wide radiating wing (18) extending parallel to the ground plane (9) nearby of it. The radiating wing (18) is connected to the foot (17) by its central part (16) and, to the excitation part (6), near its edge (8). The antenna can be used on board aircraft and machines subjected to significant temperature rises.

Description

1 -

HIGH GAIN DIRECTIVE ANTENNA

  WITH RADIANT PART SUPPORTING HEAT

  The present invention relates to a part antenna

radiant supporting heat.

  Such an antenna is used on board high speed aircraft and animated vehicles, subjected to significant temperature increases, for communications of all kinds between these aircraft and in particular the ground or satellites as well as their

  navigation, their piloting, their pursuit, for example.

  The antenna of the invention can transmit and receive on a central frequency situated in a wide range from a few hundred M Hz to a few G Hz, but with a relatively wide bandwidth, of the order

  from 10 to 15% of this central frequency.

  The antenna of the invention must above all be able to withstand temperatures exceeding 1000 degrees C. We already know, from document FR-A-8909298, in the name of the applicant, an antenna with a radiating part, comprising a massive monopolar element, comprising a foot of low height directly attached to a ground plane and a wide radiating wing which extends parallel to the ground plane close to it and is connected to it by the foot, which can be subjected to temperature conditions severe, and with excitation part, electrically connected to the radiating wing, distant from it Thanks to its crushed configuration, this monopolar antenna can easily be drowned

  in a fuselage or a protective covering thereof

  2 - this, so that its radiating wing is set back from its external surface or is flush with it and does not

  thus be too subject to temperature rises.

  Thanks to the extent of its radiating wing and its massive character, this antenna has a good bandwidth However the antenna of this previous document, whose radiating wing extends the foot and whose excitation part is connected to the center wing

  radiant, has a near-radiation pattern

  hemispherical and its gain is not very high, of the order of 3 d B; it is therefore not very well suited to certain applications which require high gain directional antennas, such as radio altimetry, by

example.

  The present invention therefore aims to propose a modified monopolar antenna adapted to the envisaged applications. To this end, the invention relates to an antenna of the type defined above, characterized in that the radiating wing is connected to the foot by its substantially part

  central and, at the excitation part, near its edge.

  Thus arranged, the antenna of the invention can have a gain of 10 d B in its axis, with an angular opening at -3 d B of the order of 50 degrees in the excitation plane E containing the electric field and of 60 degrees in a plane H perpendicular to the plane E. It will be noted that there was known an antenna known as "Imicrostrip", with radiating copper disc printed on one side of a substrate, with ground plane deposited on the other side of the substrate and the earthing of the radiating disc at its center But, for the assessment of the inventive activity involved in the invention of 3 - present application, this "microstrip" technique should not be taken into account L state of the art can only relate to antennas supporting severe temperature conditions This is not the case of "microstrip" antennas, whose printed copper layers would peel off with heat In addition, to offer its document antenna FR-A-8909298, from which it left for propose that of the present application, the plaintiff had already discarded the technique of "microstrip" antennas. It therefore had no reason, to solve its new problem, to take an opposite approach to that which had led it to its first invention. And if, by impossible, it was not admitted that the "microstrip" antennas must be discarded from the state of the art, then, this reverse approach would be precisely a pledge

inventive step.

  In an interesting embodiment of the antenna of the invention, the radiating wing is connected to the excitation part at two or four points, two by two angularly spaced 90 degrees and excited with the same amplitude and in quadrature phase, the field radiated by the antenna, with these spatial quadratures and

  temporal, then having a circular polarization.

  Advantageously, the monopolar element is made of a

single piece.

  Advantageously also, the monopolar element is disposed inside a case closed by a radome flush with the external surface of protective plates

thermal of an aircraft fuselage.

  In this case, the bottom of the box can constitute the ground plane of the antenna, the monopolar element and the box can be made in one piece and, even, the Utier box, the monopolar element and a thermal protection plate can be made in one piece. The invention will be better understood using the

  following description of an embodiment of

  the antenna of the invention, with reference to the attached drawing, in which FIG. 1 represents a sectional view of the antenna and

  Figure 2 a top view of the radiating wing.

  The antenna which will be described is mounted on the fuselage of an aircraft, covered with thermal protection plates 2 fixed to the fuselage by spacers, not shown. The antenna comprises a radiating part 4, an excitation part and a set of, here two, coaxial cables

supply 6.

  The radiating part 4 is housed in a conductive housing 7, fixed to the fuselage by spacers, not shown, and slid between protective plates 2. The antenna receiving boot has a flat bottom 9 and a cylindrical wall 10 Nearby from the free edge of the wall 10, extends, externally to it, an annular shoulder 12 for receiving the plates 2 The wall of the thermal protection plates 2, adjacent to the case 7, is shaped, near the housing 7, to present an annular recess portion 14 for receiving a protective radome 15, flush with the

  external surface of the plates 2 and closing the housing 7.

  The radiating part 4 of the antenna consists of a massive monopolar element comprising a foot 17, of low height, here perpendicular to the bottom 9 of the housing, and a planar radiating wing 18 extending parallel to the bottom 9 of the housing, shrinkage with respect to the protective radome 15 The radiating wing 18 has here the shape of a disc and it is connected to the foot 17, here cylindrical, by a central part 16 therefore also

  disc-shaped, but smaller.

  The monopolar element 4 is massive and is formed of a

single piece.

  The excitation part of the monopolar element 4 is distant from the radiating part 4 of the antenna. In the example considered, it is fixed under the fuselage by

ties.

  This excitation part is in fact made up of an amplitude and phase distribution member, on two excitation points 24, 24 ′ of the power arriving by a connector. The phase supply, between the distributor and the two points of the radiating wing 18, is effected by the conductive cores 25 of the two coaxial cables 6, including the outer conductive sheaths 26, which are flush with the bottom 9 of the housing to which, on one side, they are fixed, are brought to ground The bottom 9 of the housing 7 therefore forms the ground plane of the monopolar element 4 and the base 17 serves to ground the radiating wing 18 On the other side, the sheaths 26 of the cables 6 pass through the fuselage and are connected to

distributor.

  6 - The two excitation points 24, 24 'are located near the edge 8 of the radiating disc 18 and are angularly

  spaced 90 degrees They are in spatial quadrature.

  The supply of the two points 24, 24 ', by the distributor, is here such that they are in phase quadrature (phase shift of 90 degrees) Thus, the field radiated by the antenna which has just been described, with two excitation points in spatial and temporal quadratures, a

circular polarization.

  The coaxial cables 6 are filled with an insulating material, of the ceramic type resistant to high temperatures. The thermal protection plates 2 and the housing 7 are made of conductive refractory material, for example

  composite, carbon based protected against oxidation.

  The radiating monopolar element is, for example, of metallic or composite material, conductive and protected

against oxidation.

  The antenna which has just been described has a directional radiation diagram in its axis 5; its radiating part 4 may be subjected to severe temperature conditions, for example caused by high speeds or re-entry into the layers of

  the atmosphere; its bandwidth is satisfactory.

  In an alternative embodiment, the radiating disc 18

  could have only one excitation point.

  In this case, the polarization would be linear. It could also, for a circular polarization still, include four, in two pairs, two by two angularly spaced 90 degrees and excited with the same amplitude and in phase quadrature, these points -7 - excitation being in spatial and temporal quadratures In other alternative embodiments, with comparable performance, the geometry of the radiating wing is significantly different, with a surface, in the excitation plane, elliptical, square, rectangular or polygonal Similarly, the radiating wing could be slightly off center relative to the foot

grounding.

-8 -

Claims (5)

  1 antenna with a radiating part (4), comprising a massive monopolar element, comprising a foot (17) of low height directly fixed to a ground plane (9) and a wide radiating wing (18) which extends parallel to the plane of mass (9) close to it and is connected to it by the foot (17), which can be subjected to severe temperature conditions, and with excitation part, electrically connected to the radiating wing (18), remote from it, characterized in that the radiating wing (18) is connected to the foot (17) by its substantially central part (16) and, to the part   excitation (6), near its edge (8).   2 antenna according to claim 1, wherein the radiating wing (18) is connected to the excitation part at least a pair of two points   (24.24 ') in spatial and temporal quadratures.   3 antenna according to one of claims 1 and 2, in   which the monopolar element (4) is made of single piece.   4 antenna according to one of claims 1 to 3, in   which the monopolar element (4) is arranged inside a housing (7) closed by a radome (15) flush with the external surface of plates of   thermal protection (2) of an aircraft fuselage.   Antenna according to claim 4, in which the bottom (9) of the housing (7) constitutes the ground plane of the antenna. 9 -   6 antenna according to one of claims 1 to 5, in   which the radiating wing (18) has the shape of a disc.