FR2519476A1 - Electromagnetic feed for electronic scanning aerial - comprises dielectric substrate with spaced conductive bands forming horn shaped waveguide - Google Patents

Abstract

The unit comprises a rectangular metal box (1) of length L1, inside which, parallel to the large surfaces (3,4) is a plate made of a dielectric substrate of length L2. On one face of the substrate there are two conducting bands (7,8) symmetrically positioned w.r.t. the median axis delta of the plate. The outer edges of these bands (11,12) are parallel, and in contact with the metal box. Their inner edges however, are parallel for a part of their length (L3), and then diverge in horn shape to the outside away from the median line. This arrangement then provides a transition between (14) the transmission line (13) and the radiating element. The horn is thus formed from walls extending from the rectangular end (15) of the box.

Description

DEVICE FOR SUPPLYING A RADIANT ELEMENT
The present invention relates to a device for supplying a radiating element constituted either by a horn or by a dielectric antenna. The assembly constituted by the element and its power supply constitutes a microwave radiating source, usable as a primary source or as an elementary source of a network antenna. Such a source can in particular be used in the production of an electronic scanning antenna.

 In the prior art, the feeding of a horn is usually done by means of a rectangular or circular waveguide.

As for the power supply of a dielectric antenna, it can be done from all known types of VHF transmission lines. It is sufficient for a discontinuity to occur between the power supply line and the dielectric antenna and be adapted, that is to say that it transmits all the energy to be radiated. This supply line may be, for example, a shielded two-wire line, a ribbon line, a waveguide or a coaxial line as shown in FIG. 1. In this figure, the dielectric antenna 11 is attached to a coaxial line 211 on a metal screen 31. The core 41 of this line terminates in a strand 51 of a dipole g1, having a second strand 71 at / 4 of the end of the coaxial line.

 FIG. 2 represents a dielectric antenna 81 fed by a horn 91, itself excited by a coaxial line 110.

 The object of the invention is a device for supplying a radiating element, having mainly the advantage of a small radio footprint enabling the realization of a low-pitch distribution grating antenna.

 According to one characteristic of the invention, the device for feeding a radiating element comprises a parallelepipedal metal casing of length L1, inside which is placed, parallel to its long sides, a dielectric substrate plate of length L2 and on one side of which are deposited two conductor ribbons symmetrical with respect to the median longitudinal axis a of the wafer, the outer edges of said ribbons facing the inner walls of the housing being in electrical contact therewith and their edges facing to be screwed parallel to a length L3 less than L2, to make a slit line and which deviate from the axis (a) gradually until being in contact with the internal walls of the housing to form a transition between the slit line and the radiating element.

 Another very important advantage of this device for supplying a radiating element, comprising a slit line, lies in its use as an elementary source, as a radiating element linked to a module. This module comprises at least one phase shift means constituted by diodes arranged on a photogravity circuit designed according to the principle of the slit line. Thus, the transition from the phase shifter to the radiating element is naturally without continuity solution, that is, without the use of transitions to move from a transmission line model to another model. As a result, the radiating element is perfectly integrated with the module, resulting in a gain in space and weight as well as an improvement in the adaptation between the element and the module.

Other advantages and features of the invention will become apparent in the following description illustrated by the figures which represent, in addition to FIGS. 1 and 2 already described:
FIG. 3, an embodiment of a radiating source of the horn type powered by the device according to the invention;
- Figure 4, a longitudinal sectional view of a source of flared horn type powered according to the invention;
- Figures 5 and 6, two views in a longitudinal section of a radiating antenna supplied by the device according to the invention;
FIG. 7, an embodiment of a radiating antenna powered by the device according to the invention;
FIG. 8, a view in a median longitudinal section of a dielectric antenna connected to a slot-phase phase shifter;
- Figure 9, a part of a network antenna consisting of s (radiant Nrces powered by a device according to the invention.

 The elements bearing the same references in the various figures listed above perform the same functions in view of the same results.

FIG. 3 represents an embodiment of a radiating source consisting of a non-flared horn with a rectangular section, powered by the device according to the invention. This device consists of a parallelepipedal metal casing 1 of determined length L1, inside which is fixed a wafer 2 of dielectric substrate, of length L2 less than L1. This plate is placed parallel to the long sides 3 and 4 of the housing 1, on two shoulders or in two grooves 5 and 6 formed in the inner walls of the housing. On one side of this plate are deposited two conductor strips 7 and 8 symmetrical about the median longitudinal axis! I of the wafer, the outer edges 9 and 10 facing the inner walls of the housing are in electrical contact with those ci.De practical, this contact is obtained by welding ribbons to the inner walls of the housing or by gluing with a conductive adhesive. On a length L3 less than
L2, the edges 11 and 12 vis-à-vis are parallel, making a slit line 13 whose width of the slot is determined by the distance d constant between the ribbons. The slit line 13 is excited by a coaxial line 100, arranged perpendicularly to the slit against the metal box 1. The core of this coaxial line is extended by a photoengraved wire 101 on the dielectric wafer 2, on the opposite side to that of the slit line, the transition between this wire and the slit being constituted by a metallized adapter butterfly wing 102 quarter wave. The latter and the wire 101 are drawn in dashed lines in FIG.

 From the end 130 of this slit line 13, the distance d increases until the edges facing each other 11 and 12 come into contact with the inner walls of the casing 1, thereby forming a line to flared slit. These two ribbons thus separated constitute a transition 14 between the slit line 13 of supply and the radiating element, here in this case a rectangular non-flared horn.

 In Figure 3, the horn is flared and is made from the walls of the housing.

 The dielectric wafer 2 is disposed in the metal housing 1 so as to avoid any mode of propagation elsewhere than in the slot itself. This plate 2 is substantially in the longitudinal median plane of the housing to avoid asymmetry of the field figure. The casing is a shield of the slit line and no propagative mode should be established there.

 The radiating horn can be flared as shown in Figure 4, which is a view along a longitudinal section of a radiating source according to the invention. The horn is constituted by the walls of the housing 1 which flare out but it can also be reported. If the cross-section of the pyramidal flared horn is rectangular, its rectangular radiating aperture 150 has its two long sides parallel to the direction of the magnetic field H. At the edge of the radiating aperture 150 of the horn 15, the thickness of the latter has been reduced, as much as possible reducing the normal surface to the direction of propagation of the wave radiated by the horn. This makes it possible to avoid the appearance of surface currents and to cause so-called blind directions when such a radiating source constitutes an element of a network antenna. These directions where the power density can become very low are due to the coupling between the elementary sources.

 This phenomenon hindering a good use of such a radiating horn can be reduced by the addition of different microwave traps on the outer walls of the horn. FIG. 3 thus shows two traps 103 and 104, of a width equal to one quarter of the operating wavelength, N 14, which, by reducing an infinite impedance, suppress the circulation currents around the periphery of the radiating opening of the horn 15.

 But, the radiating horn 15 may also have a circular section for example; in this case, a conventional gradual transition must be made between the parallelepipedal metal casing 1 and the horn itself to ensure the continuity of propagation of the wave between the two.

 With regard specifically to the use of such a radiating horn supplied by means of the device according to the invention, in a network antenna, it has the advantage of reduced mechanical dimensions while having relatively large electrical dimensions thanks to the substrate dielectric constituting the wafer 2, support of the slot line 13, whose dielectric constant is chosen appropriately. This dielectric wafer 2 also makes it possible to compensate for the difference in wavelengths in the lower and upper zones delimited between the walls of the magnetic plane H of the horn and the circuit.

 According to the electromagnetic characteristics of the slot line 13 feeding the horn, the width of the slot, the dielectric constant of the wafer 2 support of said line, and its thickness are determined in a particular manner. This will depend on the nature of the transition 14 between the slot line 13 and the radiating horn, this transition being achieved by the flaring of the two conductive strips 8 and 7 in a rectilinear, or exponential, or rectilinear profile between two circular zones. when connections on the one hand to the slotted line 13 and on the other hand to the horn 15, or any other. However, to avoid the appearance of higher propagative modes in the horn, this profile, as well as the section of the housing must be relatively continuous.

 Finally, the adaptation of the slot line of the supply device to the space is obtained by the presence of the dielectric wafer whose length is chosen to modify the phase and the amplitude of the reflection coefficient.

In an exemplary embodiment, the dimensions are as follows for a given operating wavelength 2 and a dielectric constant r of the wafer equal to 10
L1 zoo L2 = 6; L3 = and for the rectangular radiating opening 16 of the horn 15
\ Ox 3) O
Having considered the case of a radiating horn in a first part of the description, there will be described in this second part, a dielectric antenna fed by the slit line feed device according to the invention.

 FIG. 5 represents a view in a median longitudinal section of an embodiment of such a radiating source. The feed device is constituted by a parallelepipedal metal casing 1 inside which is placed a wafer 2 dielectric substrate on which is formed a slot line 13, as has been explained before. Edges. 11 and 12 vis-à-vis the two ribbons 8 and 7 deviate to form a transition 14 between the slotted line and a dielectric antenna 16 placed at the opening of the housing 1. This dielectric antenna can have a cylindrical shape , conical, semi-spherical or otherwise, and be solid or hollow, of inner and outer straight sections constant or decreasing in the direction of propagation of the wave.The choice of the shape of the dielectric antenna 16 as well as that of the dielectric constant of the material from which it is made, and the respective dimensions of the metal casing 1 and the antenna itself are a function of the desired radiation patterns in the two main electrical planes E and magnetic H.

 The adaptation of a dielectric antenna thus described to the feed device is obtained by the dimensions of the slit line, the antenna itself and the value of the dielectric constant. The dielectric antenna must, in addition, have a particular shape inside the housing 1: in fact, it must have a transition 17 flared in the plane of the electric field E and rectilinear in the plane of the magnetic field H, as the FIGS. 7 and 7 are a perspective view of a dielectric antenna powered by a device according to the invention.

The appearance of the dielectric material of the antenna in the housing must take place before the end 130 of the slit line 13, thus before the transition 14, so that the electromagnetic waves emitted by the slit line 13 propagate normally in the the dielectric antenna 16 because, often, the dimensions of the housing 1 is a guide used at the cutoff frequency; only then are the evanescent modes. For this, the dielectric antenna 16 is slotted longitudinally along a length L4, so that the wafer 2 is introduced inside the slot 18.The position of the end 19 of the dielectric wafer 2 inside the slot 18 of the antenna 16 is determined to ensure the best fit between the power slot line and the dielectric antenna itself, this being due to the fact that the electric field is propagated essentially on the surface of the wafer 2 but also in the dielectric material that supports the slit line.

Also shown in FIG. 7 are three dimensions el, e2 and e3 of the dielectric antenna, el being its height at its end placed in the housing 1, e2 being its height at the opening of the housing and e3 being that at its radiant end. These three dimensions are linked by the relation
e14 e2 <e3
FIG. 6 shows another exemplary embodiment of a device according to the invention supplying a dielectric antenna, for which it has been sought to avoid any propagation of a higher mode.

For this, the mechanical dimensions of the straight section of the housing 1 have been reduced from the flaring of the slit line.

 As was said at the beginning of this description, a very important advantage of such a device for supplying a radiating element of the horn or dielectric antenna type is the possibility of constituting a module by placing upstream of this device a phase shifter 20 as shown in FIG. 8. This phase shifter 20 comprises a slot line 21 coupled to a coplanar line 22 of the same propagation axis and a device with two diodes 23 and 24, located in the coupling zone of these two lines. transmission, as described in the patent No. 2,379,196 filed in the name of the Applicant It is found that such a module has reduced dimensions and avoids insertion losses.

  As has been said previously also, a radiating element powered by a device according to the invention can be used as an elementary source of a network antenna.

 FIG. 9 shows it, taking the example of a dielectric antenna 16 fed by a slot line 13 itself placed in a parallelepipedal metal case.

Thus has just been described a device for supplying a radiating source consisting of a horn or a dielectric antenna, fed by a slot line deposited on a dielectric substrate wafer, the main advantage of which is the small radio footprint when the a dielectric substrate with a high dielectric constant is used. This therefore allows the realization of low-pitch distribution network antennas measured in
wave length.

Claims (9)

 1. Device for supplying a radiating element, characterized in that it comprises a parallelepipedal metal casing (1) of length L1, inside which is placed, parallel to its long sides (3 and 4), a plate (2) dielectric substrate of length L2 and on one side of which are deposited two conductive strips (7 and 8) symmetrical with respect to the median longitudinal axis ss of the wafer, the outer edges (9 and 10) of said strips view of the inner walls of the housing being in electrical contact with them and their edges (11 and 12) facing each other being parallel over a length L3 less than L1, to make a slit line (13) and which move away from the axis (ss) progressively until they are in contact with the inner walls of the housing (1) to form a transition (14) between the slit line (13) and the radiating element.  2. Device for supplying a non-flared radiating horn according to claim 1, characterized in that this horn (15) is made from the walls of the casing (1) which extend straightly beyond the transition (14). ).  3. Device for feeding a pyramidal flared horn with a rectangular cross section according to claim 1, characterized in that the horn (15) is constituted by the walls of the casing which are spaced apart so that the radiating aperture (150) rectangular cornet has its two long sides parallel to the direction of the magnetic field <.  4. Feeding device according to claim 3, characterized in that the thickness of the flared horn (15) is reduced to the edge of the radiating aperture (150) of said horn.  5. Feeding device according to claim 3, characterized in that the horn (15) has two microwave traps (103 and 104), placed on its outer walls and a width equal to one quarter of the operating wavelength.  6. Device for feeding an antenna. dielectric according to claim 1, characterized in that said antenna (16) is located at the opening of the housing (1) and is slotted longitudinally along a length L4 so that the dielectric wafer (2) is inserted inside. of this slot (18), the part of the antenna (16) located inside the casing having a transition (17) flared in the plane of the electric field E and rectilinear in the plane of the magnetic field H, starting before the end (130) of the slit line (13).  7. Feeding device according to claim 6, characterized in that the mechanical dimensions of the cross section of the housing are reduced from the transition (14).  8. Feeding device according to one of claims 1 to 7, characterized in that the slit line (13) is directly located in the extension of the slit line (21) output of a phase shifter (20) with diodes.  9. An array antenna using as a basic source horn or a dielectric antenna powered by a device according to one of claims 1 to 8.