FR2710458A1 - Two-wire planar antenna - Google Patents

Abstract

The subject of the invention is a two-wire antenna to which phase-shifter elements (3) are added on one of the two conducting lines (2) so that radiation from the line is created and that this radiation is a maximum at points which lie at a distance such that the currents are in phase at the end of a step difference of less than lambda /2. Application to radar aerials.

Description

BIFILAR PLANE ANTENNA
The invention relates to a flat two-wire antenna with transverse radiation and its application to radars overhead.

 In certain detection or transmission equipment using electromagnetic waves, it is necessary to have an antenna that meets the following conditions: - have transverse radiation - have a large frequency bandwidth - allow the phase center to be displaced as a function of the frequency according to a linear law so as to be able to carry out deviation measurements by the association of at least two similar antennas - to have a reduced size.

 An antenna is known which meets these criteria and which is described in patent No. 79 24897.

 However, this antenna does not make it possible to obtain the best compromise between a large bandwidth and a reduced size for a certain range of frequencies.

 In fact, in certain applications it is desired to operate the antenna at fairly low frequencies in the microwave range. Under these conditions, the geometrical location where the best radiation conditions are obtained moves away from the top of the antenna (feed point). Indeed, this place, which is located at points where the path difference between the currents flowing through the two conductors is X / 2 from the top of the antenna, moves away from this top when the frequencies are low. It is therefore necessary in this case that the antenna is large enough so that the conditions of maximum radiation are located on the antenna and not outside.

 The present invention aims to define a planar two-wire antenna having all the characteristics mentioned above while providing improvements to these characteristics and which, in addition, makes it possible to work at the lowest frequencies of the microwave range while having a very small footprint.

 The subject of the invention is therefore a two-wire planar antenna in which phase-shifting elements are added on one of the two lines so that there is creation of radiation from the line and that this radiation is maximum at points which are located at a distance such that the currents are in phase after a path difference of less than X / 2, this having the effect of obtaining the ability to work at lower frequencies and more of obtaining maximum radiation in a direction perfectly orthogonal to the plane of the antenna.

Other advantages and characteristics of the invention will emerge from the description which follows, given by way of nonlimiting example and illustrated by the appended drawings in which
- Figure I shows an embodiment of an antenna according to the prior art
- Figure 2, the antenna of Figure 1 front view
- Figures 3a and 3b show an embodiment of an antenna according to the invention
- Figures 4a, 4b, 4c show different particular embodiments of the phase shifting tips according to the invention
- Figures 5a and 5b, two non-limiting examples of grouping of antennas according to the invention
- Figures 6a and 6b, the locations of a reflective element attached to the antenna according to the invention
- Figure 7, a particular embodiment of the antenna according to the invention for obtaining an inclined polarization.

 A two-wire line whose conductors are sufficiently close to each other has a very weak radiation because the conductors being traversed by a current in phase opposition, their respective radiations cancel each other out.

 If, by any means, one of the conductors has its electrical length increased relative to the other, the conditions for radiation will be created which will be maximum at the point where the conductors will be traversed by phase currents .

 This method is used to create the radiation from the antenna of the prior art shown in Figures 1 and 2.

 Figure 1 of the prior art shows the antenna in perspective.

It comprises a dielectric plate limited by two planes P1 and P2, the thickness of which is small, and on which are fixed on either side, and respectively, two conductive metal lines 1 and 2, for example by etching according to the known technique of printed circuits; these lines have N folds which are arranged so as to be inscribed in an opening angle a. One of the conductive lines 2 is extended by a length A1 relative to the other conductive line at each folding.

 Under these conditions, when supplying the two lines in phase opposition at point 0, vertex of the angle in which the folds are registered, one obtains from this point 0, a variation of the relative phase of the two conducting lines 1, 2 directly function of the distance to the point 0 of the conductive line element considered. When this phase shift reaches 1800 the two conductors are traversed by electric currents in phase, which are the conditions of maximum radiation.

 So that the direction of maximum radiation is perpendicular to the plane of the antenna, that is to say that the radiation is transverse, it is necessary that two neighboring elements of conducting lines, for example the points A of the second line and B of the first line, are in phase.

 This supposes that the following two conditions are fulfilled simultaneously for a maximum radiation wavelength - path difference of X / 2 between the conducting lines 1 and 2 - average length of the conducting line elements containing the points A and B equal to X / 2.

 The consequence of these two conditions is that the phase center of the antenna thus formed deviates from the feed point 0 in a manner proportional to the wavelength.

 The disadvantage resulting from these conditions is that for low frequencies in the microwave range, the geometrical place where the best radiation conditions occur is further from the top of the antenna as a result of which the antenna must be longer and therefore has a larger footprint.

 An antenna according to the invention is shown in Figures 3a and 3b. The antenna is seen in perspective. In Figure 3a there is shown the antenna on a dielectric support. This support consists of a dielectric plate 10 of small thickness limited by two planes P1 and P2, and on which are fixed on either side, by techniques known from the prior art, and respectively, two conductive metal lines 1 and 2.

 These two lines 1 and 2 have N folds so as to be inscribed in an opening angle a. Each fold of the conductive line 2 is extended with respect to the other conductive line 1 by a phase-shifting tip 3. These tips preferably have the same width b as the folds of the line, this width between neighboring line elements being limited below. by coupling phenomena.

 The height H., i being an index indicating the order with respect to the vertex 0 of the antenna, of a half conductive line element 2 is increased by a height h. corresponding to the height of the phase shifting tip added to this line element. The different tips therefore have a different height, so that the line 2 thus extended is inscribed in an opening angle ss greater than a and having the same vertex 0.

 It is quite obvious that the spacing d between two successive elements of the same conductive line can, in another embodiment not shown, vary in proportion to the distance of these line elements to the feed point 0. This variant in the geometry of the folds, implies that the variations d of each fold are proportional to the distance from the feed point 0 of the antenna.

 These two examples of geometry for folding are not limiting. In particular, it is conceivable that the line elements delimited by the successive folds are not straight, or even parallel with respect to each other; moreover the distance between two successive line elements can vary according to any predetermined law, other than a linear law.

When the two lines 1, 2 are supplied at point 0 in phase opposition, one obtains from this point 0 a variation of the relative phase of the two conducting lines 1 and 2 directly function of the distance to point 0 of the element of conductive line considered. This phase shift gives rise to a radiated mode also called even mode; this mode of propagation of the currents reaches its maximum when the following conditions are met - the path difference between two conductive elements located opposite and forming a pair is equal to D, D being less than
Bl2 - the average length of the conductive line elements containing the points A of the second line and B of the first line which constitute the geometrical place where the best radiation conditions are met, is substantially equal to 0.3A.

 In FIGS. 4a, 4b, 4c three particular embodiments of the phase-shifting ends have been shown.

 FIG. 4a represents the phase-shifting end piece 3 as it is also shown in FIGS. 1 and 2. This end piece consists of a section of line 4 folded, of height h. which extends and closes line 2 at points C and D, these points being moreover linked together by the line section which forms a folding of the line element considered.

 FIG. 4b represents a phase shifting end piece 3 constituted by two line sections 5 which extend the line element considered on either side of points C and D, the end piece being open at the ends of these sections.

 FIG. 4c represents a phase shifting tip 3 constituted by a conductive plate 6. Two sides of this plate extend the line 2 on either side of the points C and D. A third side closes the line between the points C and D.

 The geometry of these end pieces can vary according to the geometry chosen for the folds, if the folds have a trapezoidal shape, the end pieces will also have a trapezoidal shape.

 The phase shifting end pieces 3 create the required phase shift and moreover participate in the radiation of the antenna unlike line increases of the antenna according to the prior art. This participation of the tips 3 to the radiation has the effect of causing maximum radiation closer to the top of the antenna (where the power is supplied). This maximum radiation takes place at a distance equal to 0.2A. Indeed, from the vertex 0 on the axis OX where the phase center of the antenna moves. The tips 3 also contribute to obtaining transverse radiation as well as improving the gain of the antenna.

 An elementary antenna as described above can be used for transmitting and / or receiving very wide frequency band (frequency ratio of the order of 10) of a rectilinear polarized wave, for example in a signaling device. electromagnetic detection.

 The association of at least two of these antennas can be used as an aerial deviation meter; the phase difference between the signals received by two neighboring antennas is then measured, which can be supplied either in phase or in phase opposition as shown in FIGS. 5a and 5b.

 Arrays of several antennas of this type can be done in many different ways. For a couple of two antennas, it is possible, for example, to arrange them on the same plane and symmetrically with respect to a point or with respect to a straight line of this same plane as shown in the examples corresponding to FIGS. 5a and 5b.

 The grouping of two elementary antennas, whether supplied in phase or in phase opposition makes it possible, because of the symmetry that they present, to obtain a bearing diagram independent of the frequency. Likewise for these same reasons of symmetry, the phase center being at the center C of the antenna consisting of these two elementary antennas whatever the frequency, the antenna can be used as primary source for a reflector.

 In order to obtain the transverse radiation in one direction, a reflecting plane P3 or a cavity reflecting the electromagnetic waves is used. This plane can for example be constituted by a metal plate 11, covered or not with absorbent disposed parallel to this antenna at a distance close to À M14 or À M is the minimum wavelength of the antenna (maximum frequency of the use band). This reflecting plane can be arranged in an oblique plane 12 which passes through the point 0 and which makes an angle y with the plane P2 so that each element of conducting line of order i is situated with respect to the reflecting plane, at a distance less than or equal to Ai / 4, where X. i is the wavelength corresponding to the frequency for which an element of order i of line radiates. These two alternative embodiments are illustrated by FIGS. 6a and 6b.

 In an embodiment which has not been shown, it is possible to combine parallel planes and inclined planes. The reflecting plane is thus constituted by a succession of inclined planes and parallel planes.

 To receive horizontally polarized electromagnetic waves and vertically polarized waves, four elementary antennas are described orthogonally and in the same plane. This variant embodiment has not been shown.

 The polarization of the waves being parallel to the strands of the two-wire line, the antenna is obtained without rotation, but by inclining the strands relative to the axis of expansion 0X by an angle ce (i.e. (p = 450 for example ), an antenna with inclined polarization which, apart from the polarization differences, retains all the properties of the vertical polarization antenna, which is shown in Figure 7.

Claims (14)

 1. Flat two-wire antenna with transverse radiation comprising a first (1) and a second (2) conductive lines arranged opposite each other on a first (P1) and a second (P2) parallel planes, the first and respectively the second line conductive (1, 2) having N folds delimiting conductive elements which are each arranged opposite a conductive element of the other line, respectively forming a pair with the conductive elements of the other line, characterized in that that each folding of the second line (2) is extended by a conductive element introducing a phase shift between the currents flowing in the conductive line so that a radiant mode begins and reaches its maximum after a lower path difference à À / 2 where is the wavelength of the supply wave, each conductive element of the second line (2) having an electrical length greater than elements of the first line so that the second line (2) is inscribed in an opening angle ss of vertex 0, greater than a, a being the aperture angle of vertex 0 in which the first line is inscribed (1), 0 being the feed point of the antenna.  2. Antenna according to claim 1, characterized in that the phase-shifting elements (3) consist of a folded line section (4) which extends and closes the line (2) at extreme points of the line (C and D) , these points being moreover connected to each other by the line section which forms the folding of the line element considered.  3. Antenna according to claim 1, characterized in that the phase-shifting elements (3) consist of two line sections (5) which extend the element of the line considered on either side of two end points (C and D) interconnected and forming each fold.  4. Antenna according to claim 1, characterized in that the phase-shifting elements consist of a plate (6), two sides of which extend the second line (2) and a third side of which closes the line between the two extreme points (C, D ) of each folding.  5. An antenna according to any one of claims 1 to 4, characterized in that the conductive line elements, determined by the N folds, are parallel.  6. Antenna according to any one of claims 1 to 5, characterized in that the conductive line elements, determined by the N folds are rectilinear.  7. Antenna according to any one of claims 1 to 5, characterized in that the conductive line elements, determined by the N folds are trapezoidal.  8. An antenna according to any one of claims 1 to 7, characterized in that, for each conductive line (1, 2) the distance between two consecutive parallel conductive elements varies with the distance of the first of these line elements from the supply point 0 of the conductive line (1, 2) according to a predetermined function, the widths of the phase-shifting elements varying according to this same function.  9. An antenna according to any one of claims 1 to 8, characterized in that the first and second conductive lines (1, 2) are fixed on either side of the same dielectric plate (10).  10. Antenna according to any one of claims 1 to 9, characterized in that it includes a planar reflecting surface (11) parallel to the first and second planes of the two-wire line and located at a distance close to λ / 4, M being the minimum wavelength of the antenna.  11. Antenna according to any one of claims 1 to 9, characterized in that it comprises a reflecting surface (12) passing through the point 0 and forming with the first or second plane (P1 or P2) of the two-wire antenna an angle y such that each conducting element of the line of said plane (P1 or P2) is distant from said reflecting surface by a length less than or equal to substantially a quarter of the wavelength at which the element radiates.  12. An antenna according to any one of claims 1 to 11, characterized in that the reflecting surface (12 or 13) consists of a succession of inclined planes and parallel parallel planes.  13. Antenna according to any one of claims 1 to 12, characterized in that the strands constituting each line element are inclined by an angle tp relative to the axis OX of the angle, axis on which is capable of move the antenna phase center.  14. Use in a radar antenna of at least two two-wire planar antennas according to any one of claims 1 to 13, characterized in that these antennas are connected in parallel and supplied in phase or in phase opposition, or else, supplied separately, in phase or out of phase.