EP0174250A1 - Device for receiving dual polarized microwave signals - Google Patents

Abstract

A device for receiving dual polarized microwave signals, including a first waveguide connected to a receiving antenna and to a first substrate bearing a first sensor perpendicular to the longitudinal axis of the first waveguide, a second waveguide having the same longitudinal axis and the same dimensions as the first waveguide, and which is connected to a second substrate having a second sensor perpendicular to the longitudinal axis of the second waveguide. Surrounding the second waveguide is a tube having tongues at opposed ends which cooperate with slots formed in the first and second substrates. The opposed tongues of the tube are staggered by 90 DEG so that upon insertion of the opposed tongues of the tube within the slots of the first and second substrates, sensors formed on these substrates are arranged orthogonally with respect to one another. The tongues and cooperating slots assure mechanical integrity. A metallic blade is mounted in axially extending diametrically opposed slots formed in the second waveguide in the tube to maximize decoupling between the dual polarized signals being received.

Description

The invention relates to a device for receiving microwave signals with double polarization, consisting of simple elements which allow rapid and easy mounting without subsequent adjustments, and which confer sufficient overall rigidity.

This device is more particularly intended for the reception of microwave signals with double polarization transmitted for television, for example from geostationary satellites. It is intended to be used in reception stations, in combination with the active elements fitted to the microwave heads of said stations.

More generally, the device can be used for the reception of all microwave signals with double polarization, by adapting some of its elements to the frequency range for which it is intended.

A signal or even a wave is said to have double polarization when it does not propagate on a plane, as is the case for a signal with rectilinear polarization (also called plane wave), but around an axis determining the direction. signal propagation. This is the case for waves with circular polarization, or even waves with elliptical polarization.

A double polarization wave can be considered as the superposition of two waves with rectilinear polarization.

The polarization is circular when the amplitude of the field vector (electric or magnetic) resulting from the superposition of the two waves is constant around the axis of propagation: more precisely, the end of the field vector describes a circle around the axis , in projection on a plane perpendicular to this axis.

A wave with circular polarization is the result of two plane waves, orthogonal to each other, and whose maximum amplitudes and frequencies are equal, but between which there is a phase shift of 90 °.

The polarization is said to be elliptical when the amplitude of the field vector varies around the axis of propagation. Its end describes an ellipse, projected onto a plane perpendicular to the axis.

An elliptically polarized wave is the result of two plane waves, orthogonal, whose maximum amplitudes are different.

Circular polarization is mainly used in satellite tracking installations or in space communication installations. The consequences of the Faraday effect which exists in the ionosphere are then lessened, and the reception is better. Circular polarization is also used in terrestrial radars, in order to limit parasitic echoes due to clouds.

In order to exploit on reception a wave transmitted in double polarization, it is known to decompose this wave into two plane waves, then to analyze each of the components obtained.

It follows that a device for receiving waves or microwave signals with double polarization must include means for ensuring the reception and processing of two microwave signals with rectilinear polarization.

In known devices for receiving microwave signals with rectilinear polarization, the signal is picked up using a probe which feeds the input of a microwave head.

The microwave heads include a preamplifier stage connected to the probe, in order to amplify the signal received in the centimeter wave band. A heterodyne converter, consisting of a local oscillator and a mixer, allows the frequency of the signal received by the probe to be transposed to a lower frequency, for example in the HF band; then, an amplifier acts on the signal transposed before its exploitation.

These various constituents include elements in microstrips distributed over dielectric substrates of greater or lesser thickness depending on whether they are associated with the decimetric wave circuit or the centimeter wave circuit. Conductive sections are produced by metallization on these substrates and their width varies according to the frequency band for which they are intended.

The probe to pick up the signal is, in these different circuits, produced using a metallization placed on one of the substrates, and is located inside a waveguide connected to the antenna. reception.

The production of a device for receiving microwave signals with double polarization has drawbacks because this device must have two probes and two sets of substrates.

First of all, the probes must be arranged to receive signals orthogonal to each other. The circuits supplying the microwave heads must then not interfere; assembly must be rapid, does not require subsequent adjustments and has sufficient rigidity.

The device of the invention verifies these different conditions.

According to the invention, a device for receiving a dual polarization microwave signal comprises an antenna for directing the signal to a waveguide at the input of which is a depolarizer which makes it possible to decompose the signal into two orthogonal components , with rectilinear polarization, and is characterized in that a probe produced by metallization of a first dielectric substrate is placed inside the waveguide, near its exit, perpendicular to the longitudinal axis of this guide , and is kept away from a second probe produced by metallization of a second dielectric substrate, which is placed perpendicular to the longitudinal axis of the guide, near one end of a second waveguide of the same section internal than the first, and which is located in the extension of the first, and in that means make it possible to ensure the orthogonality of the two probes with respect to the axis and one with respect to the other from the mounting of as a whole, and in that means are provided for decoupling and adapting the probes without subsequent adjustments.

In a preferred embodiment of the device of the invention, the two probes are kept at a distance from each other thanks to the second waveguide, at the ends of which are placed the substrates carrying each probe, and the orthogonality between the two probes is ensured by means of a tube in which the waveguide is fitted, and at the ends of which there are tongues identical from one end of the tube to the other, but offset by 90 °, intended to cooperate with slots made in the substrates, and positioned on one substrate and on the other at the same relative locations with respect to the probes.

• - La figure 1 montre une antenne qui peut être utilisée en association avec le dispositif de l'invention.
• - La figure 2 est une vue éclatée du dispositif de l'invention, permettant de montrer ses éléments constitutifs.
• - La figure 3 est une vue en coupe du dispositif de l'invention lorsqu'il est assemblé.
• - La figure 4 est une vue en coupe d'une variante du dispositif de l'invention lorsqu'il est assemblé.
• - La figure 5 représente le détail de l'une des parties du dispositif de l'invention.

Other characteristics and advantages of the invention will become apparent with the description of some embodiments of the device, made with reference to the appended figures in which:

• - Figure 1 shows an antenna which can be used in combination with the device of the invention.
• - Figure 2 is an exploded view of the device of the invention, to show its constituent elements.
• - Figure 3 is a sectional view of the device of the invention when assembled.
• - Figure 4 is a sectional view of a variant of the device of the invention when assembled.
• - Figure 5 shows the detail of one of the parts of the device of the invention.

The device for receiving dual polarization waves comprises, as shown in FIG. 1, a reception antenna of the CASSEGRAIN type consisting of a paraboloidal reflector 1, at the focus of which is a hyperboloidal reflector 2 which returns the electromagnetic waves to a reception horn 3 associated with a waveguide 4 whose role is to direct the waves towards the active elements of the high-frequency circuits which are at the end of the waveguide opposite the antenna.

The circular polarization wave is decomposed into two plane waves, in known manner, using a depolarizer located at the outlet of the reception horn 3, in the wave guide 4. This depolarizer, not shown in the figures, is in dielectric or metal strip.

The two waves thus obtained are orthogonal to each other and continue their propagation inside the waveguide 4. The device of which FIG. 2 shows, in exploded view, the constituent elements allows the reception of these two orthogonal waves.

The waveguide 4 is in the form of a cylinder open at its two ends. One end is connected to the outlet of the reception horn 3 of FIG. 1. At the other end, intended to be near the reception circuits, there is a recess 41 for the passage of the electrical connection between a probe 51 and the microwave head (not shown) associated therewith.

The device also comprises a first set 5 of microwave circuits in microstrips on which the first probe 51 is located for the reception of one of the two waves resulting from the decomposition of the double polarization signal by the depolarizer.

In a preferred embodiment of the invention, this assembly is assembled according to the technology protected by French Patent No. 2,522,885 of the applicant.

It consists of two superimposed substrates: a thin substrate SM 5 intended for the centimeter wave band and a thick substrate SE 5 intended for the decimeter wave band.

The probe 51 intended for reception is produced by metallization of the face of the thin substrate SM 5 not facing the thick substrate SE 5.

This probe 51 has an almost triangular shape (axial section of a "carrot"), the top of which is substantially in the center of a circle, delimited on the assembly of substrates by slots F ₅₂ , Fj3, F54 in the form arcs. These slots cross the two SM 5 and SE 5 substrates right through. A metallization, not shown, is located between the two substrates and serves as a ground plane.

The thin substrate SM 5 is intended to be located opposite the end of the waveguide 4 which carries the recess 41.

A guide 6, cylindrical, the inside diameter of which is the same as the inside diameter of the guide 4, is intended to be placed, by one of its ends, opposite the thick substrate SE 5. Near this end, in the wall of the guide, are formed two thin slots, diametrically opposite, and parallel to the longitudinal axis of the guide. Only one of these slots 63 is visible in the figure. These slots are intended to receive a metal blade 61 for the adaptation of the probe 51 and the decoupling between the two accesses as will be explained later.

At the other end of this guide, there is a recess 62 which allows the passage of the second probe (for receiving the second signal).

This guide 6 also has the same external diameter as the guide 4 connected to the horn.

A tube 7 has an internal diameter equal to the external diameter of the guide 6, so that the latter can be fitted inside.

The end of the tube 7 intended to be opposite the thick substrate of the assembly 5 has extensions in the form of tongues L ₅₂ , L _{53 '} L ₅₄ complementary to the slots F ₅₂ , F _53' F ₅₄ which pass through the two substrates SM 5 and SE 5, so that these tongues can be engaged in the slots, and so that the tube 7 is made integral with the assembly 5.

The other end of the tube 7 is also terminated by tabs L ₈₂ , L ₈₃ , L ₈₄ , similar to those of the other end, but offset by 90 ° relative to the latter.

The length of the tube 7, without the tongues of each end is equal to the length of the guide 6. A recess 71 is formed between two tongues L ₈₂ and L _{83 '} so as to be opposite the recess 62 of the guide 6 when that is in place, to allow the passage of an electrical connection between a second probe and a high-frequency head.

Two slots, of which only one 72 is visible, are formed in the wall of the tube 7, parallel to its longitudinal axis to allow the metal blade 61 to be placed in the slots 63 of the guide 6.

The slots 63 of the guide 6 and 72 of the tube 7 are placed so that the adaptation blade 61 of the probe 51 is parallel to the longitudinal axis of this probe when the tabs L ₅₂ , L ₅₃ , L54 of the tube 7 are in place in the slots F ₅₂ , F ₅₃ , F ₅₄ of the assembly 5 carrying this probe 51.

The tongues of the tube 7 and the slots of the corresponding assembly 5 are arranged so that only one positioning of this assembly is possible.

A second assembly 8 comprising elements in microstrips is identical to the first and comprises a probe 81 and three slots F ₈₂ , F ₈₃ , F ₈₄ intended to cooperate with the tongues L ₈₂ , 83, L ₈₄ of the other end of the tube 8 .

The guide transition serving as probe 81 is produced using a quasi-triangular metallization formed on the thin substrate SM 8 of the second set 8. This probe is connected to the amplifier stage of the high-frequency head by a connection in microstrips passing through the recesses 71 of the tube 7, and 62 of the guide 6.

A thick SE 8 substrate also makes up this set 8 of microstrips, according to the technology described in French Patent No. 2,522,885 already cited.

Slots F, ₂ , F ₈₃ , F ₈₄ are made in the thickness of the two substrates, identical to the slots F ₅₂ , F ₅₃ , F ₅₄ of the first set of circuits, and are intended to cooperate with the tongues L ₈₂ , L ₈₃ , L ₈₄ of tube 7.

A cylindrical cup 9, closed off by a short-circuit bottom, has an internal diameter equal to the internal diameter of the guide 6 and an external diameter equal to the internal diameter of the tube 7. This cup is designed to fit into the tongues L ₈₂ , L ₈₃ , L84 when the tube 7 is in place on the set 8 of microstrip circuits.

Figures 3 and 4 show, in a section passing through the longitudinal axis of the probe 51, the device when the constituent elements are in place.

The waveguide 4 intended to be connected to the antenna is in contact with the thin substrate SM 5 of the first set 5 of microwave circuits in microstrips. The recess 41 allows the passage of the probe 51 and its electrical connection with the microwave head with which it is associated. The second guide 6 is placed between the two sets 5 and 8 of microstrip circuits. By its presence, it allows the substrates SM 5, SE 5, SM 8, SE 8 and consequently the probes 51 and 81 which it carries respectively to be on perfectly parallel planes, while being perpendicular to the longitudinal axis of the guides. This is made possible because the ends of the guides are in cross section. The tube 7 thanks to the tabs engaged in the slots of the sets 5 and 8 of microstrip circuits allows the probes to be orthogonal to each other, because the tabs are similar from one end to the other but offset by 90 °, and because the sets 5 and 8 of microstrip circuits are identical, and in particular have their slots placed in the same places with respect to the probes.

Firm support of the waveguide 4 relative to the first set 5 of microstrip circuit is ensured by means of the tongues L ₅₂ , L ₅₃ , L ₅₄ as shown in FIGS. 3 and 4.

The metal blade 61 is welded, after having been put in place, both in the slots 63 and 72 of the guide 6 and of the tube 7. It is placed parallel to the longitudinal axis of the probe 51 and thus reflects all the waves which are parallel to it. Therefore, the probe 51 is adapted.

The distance between the two probes is equal to a guided wavelength. For the adaptation of the probe to be effective, the middle of the metal plate 61 must be located at a distance from the probe 51 equal to a quarter of the guided wavelength. Thus, this metal strip returns to the probe 51 the component of the field which is parallel to it, which allows the adaptation of the probe 51 and the establishment of a good decoupling between the two accesses.

The termination cup 9 is held on the assembly in a manner similar to the waveguide 4: the tabs L 821 L ₈₃ , L ₈₄ passing through the slots of the second set 8 of circuits allow this holding. The bottom of this cup is kept parallel to the set 8 of circuits, at a distance from the probe 81 slightly less than a quarter of the guided wavelength. This short-circuit bottom allows the adaptation of the second probe 81.

It is possible to improve the decoupling by replacing the cup 9 with a metal blade 91 parallel to the longitudinal axis of the probe 81, as shown in FIG. 4. This blade is held in a circular guide 9 bis with the same internal diameters and external than guides 4 and 6.

This metal blade 91 is held in the guide 9a by virtue of slots diametrically opposite and parallel to the longitudinal axis of this guide, as was the case for the metal blade 61 of the guide 6 and of the tube 8.

Decoupling can also be improved by placing a resistive blade between the metal blade 61 and the second probe 81 parallel to the blade 61. This blade will absorb the residue of the component of the field parallel to the first probe 51 which will not have been reflected by the metal blade 61 and which will not have been picked up by the first probe 51.

The use of this blade is essential when the decoupling between the two ports must be greater than the values required by the criteria for reception of satellite television programs.

FIG. 5 represents a partial view, on the thin substrate side SM 5, of the first set 5 of circuits in microstrips. The second set 8 of microstrip circuits also has the structure shown in this FIG. 5.

The slots F ₅₂ , F ₅₃ , F 54 intended to cooperate with the tongues of the tube 7 appear in this figure. An annular metallization 10 has an external diameter equal to the internal diameter of the slots and an internal diameter equal to that of the waveguide 4. This metallization is carried out on the thin substrate SM 5 and is connected by a mass transfer rivet R to the ground plane which, as we recall, is located between the two substrates SM 5 and SE 5.

The probe S is connected via a link 11 in microstrips to the rest of the circuits making up the microwave head 12.

This metallization allows, when the device is fully assembled, that the waveguide 4 is connected to ground.

The similar metallization on the thin substrate SM 8 of the second set of microstrip circuits allows the contact of the waveguide 6 located between the two sets of microstrip circuits with the ground plane between the thin substrates SM 8 and thick SE 8 of the second set of circuits.

Preferably, electrical contact with the ground is ensured by producing a weld bead between the guide 4 and the metallization 10 of the first set of circuits or between the guide 6 and the corresponding metallization of the second set of circuits.

Preferably, to ensure good mechanical rigidity to the assembly, weld points are provided between the waveguide 4 and the tongues L52, L _{53 ′} L ₅₄ and between the cup 9 or the guide 9a and the tongues L ₈₂ , L ₈₃ , L ₈₄ of tube ⁷ .

Claims (12)

1. Device for receiving a dual polarization microwave signal comprising, in association with an antenna (1, 2, 3), a waveguide (4) at the entrance of which is a depolarizer, characterized in that that a first probe (51) produced by metallization of a first thin dielectric substrate (SM 5) is placed inside the waveguide (4), near its outlet, perpendicular to its longitudinal axis, with distance from a second probe (81) produced by metallization of a second thin dielectric substrate (SM 8), which is also placed perpendicular to the longitudinal axis of the guide (4), near one end of a second guide (6), of the same internal section as the first guide (4), and located in the extension of this first guide, and in that means make it possible to ensure the orthogonality of the two probes between them as soon as the assembly of the assembly and in that means are provided for decoupling and adapting the probes without subsequent adjustments. 2. Device according to claim 1, characterized in that it comprises a tube (7) of internal diameter equal to the external diameter of the second waveguide (6), so that this guide can be fitted inside this tube, and in that the ends of this tube include tongues (L ₅₂ , L ₅₃ , L ₅₄ and L ₈₂ , L ₈₃ , L84) ^identical and offset by 90 ° from one end to the other, and in that the substrates on which the probes are placed have slots (F52, F ₅₃ , F54 and F ₈₂ , F ₈₃ , F ₈₄ ) complementary to the tongues, having the same relative locations with respect to the probes (51, 81), which allows, when the tabs are engaged in said slots, to ensure orthogonality between the two probes. 3. Device according to any one of the preceding claims, characterized in that the guides (4, 6) have a circular section. 4. Device according to claim 3, characterized in that a metal blade (61) is placed in slots (63) of the guide (6) and (72) of the tube (8), diametrically opposite and produced parallel to the longitudinal axis of said guide and tube, in that this blade is made integral with the guide (6) and the tube (7) by welding, and is placed parallel to the first probe (51). 5. Device according to claim 4, characterized in that the middle of the blade (61) is at a distance from the first probe (51) equivalent to a quarter of the guided wavelength in order to adapt the first probe (51 ) by returning to it the component of the field which is parallel to it. 6. Device according to claims 4 and 5, characterized in that a resistive blade is placed between the second probe (81) and the blade (61), parallel to the latter, so as to attenuate the residue of the field component which is parallel to it and which is not reflected by the blade (61), to improve the decoupling between the two accesses. 7. Device according to any one of the preceding claims, characterized in that the waveguide (4) in contact with the antenna (1, 2, 3) is in contact with a metallization (10) of the thin substrate (SM 5) of the first set of microstrip circuits, has a recess (41) for the passage of the probe (51) of this first set, and is held firmly on this set of circuits thanks to the tabs (L52, L53, L54 ) of the tube (7) passing through this assembly (5), and inside which it is fitted. 8. Device according to any one of the preceding claims, characterized in that an annular metallization is formed on the thin substrate (SM8) of the second circuit assembly (8) in microstrips, and in that one of the ends of the second waveguide (6) is in contact with this annular metallization which is on the other hand connected to the ground plane of this substrate (SM 8) by a mass transfer rivet (R). 9. Device according to any one of the preceding claims, characterized in that a cup (9) having a bottom of short-circuit is fitted into the tabs (L ₈₂ , L83, ^L ₈₄ ) passing through the second set (8) of circuits, to ensure the adaptation of the second probe (81). 10. Device according to any one of claims 1 to 8, characterized in that a metal blade (91) is engaged in slots of a guide (9a) diametrically opposite and parallel to the longitudinal axis of this guide and in that this guide is fitted into the tongues (L82, L83, L ₈₄₎ of the tube (7) passing through the FEN ^te s (F82, F _83, F ₈₄₎ of the second set of circuits in order to adapt the second probe (81) and to improve the decoupling between the two ports. 11. Device according to any one of the preceding claims, characterized in that the assemblies (5, 8) of circuits carrying the two probes (51, 81) are each composed of a thin substrate (SM 5, SM 8) and of a thick substrate (SE 5, SE 8), superimposed, and between which there is a ground plane. 12. Device according to any one of the preceding claims, characterized in that the antenna with which it is associated comprises a paraboloidal reflector (1), at the focal point of which is a hyperboloidal reflector (2) which returns the waves to a horn (3) reception.

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