FR3119942A1 - Non-reciprocal microwave component - Google Patents

Abstract

Non-reciprocal microwave component comprising three waveguides and a central resonator (6) comprising upper (12) and lower (14) walls around a resonant volume (10), each waveguide comprising a zone for propagation of electromagnetic waves, the central resonator and the waveguides being arranged so that electromagnetic waves circulate between the resonant volume and the propagation zone of the waveguides, the upper and lower walls comprising upper conductive surfaces (26) and lower (28), oriented towards the resonance volume and facing each other, the central resonator comprising two elements, one ferromagnetic and the other ferromagnetic or dielectric, (15A, 15B) in the resonance volume, stepped in a direction (Z-Z) orthogonal to the upper wall and separated by a dielectric layer (30), one element being in contact with the upper conductive surface and the other element being in contact with the lower conductive surface. Figure for abstract: Figure 2

Description

Non-reciprocal microwave component

The present invention relates to a non-reciprocal microwave component comprising at least three waveguides and a central resonator, the central resonator comprising an upper wall and a lower wall extending on either side of a resonant volume for the propagation of electromagnetic waves, each waveguide extending along a respective axis of propagation, each waveguide comprising a propagation zone for the propagation of electromagnetic waves, the central resonator and each waveguide being arranged so that electromagnetic waves can circulate between the resonant volume of the central resonator and the propagation zone of each waveguide.

The invention applies to the field of microwave components, in particular based on microwave transmission lines.

PRIOR ART

Among the microwave components, the non-reciprocal components ensure essential functions such as a circulator function or an isolator function, in order to ensure a switching of the radiofrequency signals.

Conventionally, such non-reciprocal components comprise a ferromagnetic ceramic element which, once magnetized, allows such switching.

For example, it is known to produce a circulator comprising three waveguides extending at 120° from each other and connected, along a Y junction, to the same central ferrite resonator which gives the circulator its non-reciprocity. . Such a resonator is, conventionally, an Okada resonator comprising two identical ferrite elements stacked in a direction orthogonal to a plane in which the waveguides extend. More specifically, each ferrite element is bonded to a respective metal pad arranged between said ferrite element and a corresponding wall among two electrically conductive walls of the resonator facing each other. In this case, the two ferrite elements are spaced apart by a dielectric layer. These metal studs act as a quarter-wave impedance transformer, which gives the circulator a wide bandwidth.

Nevertheless, such a circulator does not give complete satisfaction.

Indeed, the use of such metal pads constrains maintaining a minimum thickness between the conductive walls facing the component. As a result, such an architecture strongly limits the possibilities of miniaturization of such components, which is detrimental for space applications, in particular, where the miniaturization of radiofrequency components or subsystems constitutes a capital issue.

An object of the invention is therefore to propose a non-reciprocal microwave component which can be easily miniaturized, while having a satisfactory bandwidth.

To this end, the subject of the invention is a non-reciprocal microwave component of the aforementioned type, in which the upper wall, respectively the lower wall, comprises an upper conductive surface, respectively a lower conductive surface, oriented towards the resonance volume , the upper conductive surface extending opposite the lower conductive surface,

the central resonator further comprising a first ferromagnetic element and a second ferromagnetic or dielectric element,

the first ferromagnetic element and the second ferromagnetic or dielectric element being arranged in the resonance volume, and being stepped in a direction orthogonal to the upper wall, being separated by a dielectric layer,

the first ferromagnetic element being in contact with the upper conductive surface and the second ferromagnetic or dielectric element being in contact with the lower conductive surface.

Thanks to the invention, it is possible to manufacture a non-reciprocal microwave component economically and quickly. In addition, the non-reciprocal microwave component according to the invention has a gain in volume and high performance compared to the state of the art. In particular, the absence of a metal pad makes it possible to obtain a thin structure for the component.

According to other advantageous aspects of the invention, the non-reciprocal microwave component comprises one or more of the following characteristics, taken separately or in all technically possible combinations:
- The first element and the second element differ in their shapes and/or in the materials from which they are made.
- the upper wall and/or the lower wall is a substrate comprising a metallized face, the metallized face forming the corresponding conductive surface among the upper conductive surface and the lower conductive surface.
- the first ferromagnetic element and/or the second element when it is ferromagnetic is made of ferrite, for example a hexagonal ferrite.
- the first ferromagnetic element and/or the second element when it is ferromagnetic is made of an anisotropic material, preferably a hexagonal ferrite.
- the dielectric layer is a gas or vacuum layer or a solid layer.

In addition, the subject of the invention is an on-board radio frequency system comprising at least one non-reciprocal microwave component, as previously presented.

The invention will be better understood using the following description, given solely by way of non-limiting example and made with reference to the appended drawings in which:

is an exploded and perspective view of a first embodiment of a non-reciprocal microwave component according to the invention;

is a sectional view of the microwave component of the , along a plane of section orthogonal to a plane in which waveguides of said microwave component extend;

is a graph illustrating the evolution of the transmission coefficient S _{2 1} of the non-reciprocal microwave component according to the invention, as a function of the frequency;

is a graph illustrating the evolution of the reflection coefficient S ₁₁ of the non-reciprocal microwave component according to the invention, as a function of the frequency; And

is a graph illustrating the evolution of the insulation coefficient S ₁₂ of the non-reciprocal microwave component according to the invention, as a function of the frequency.

DETAILED DESCRIPTION

A non-reciprocal microwave component 2 (hereinafter called "component 2") according to one embodiment of the invention is schematically illustrated by Figures 1 and 2.

Such a component 2 is, in particular, intended to provide a circulator function, or else an isolator function.

Component 2 is intended to be integrated into an on-board radio frequency system, in particular on board a spacecraft (not shown).

Component 2 has at least three 4 waveguides and a central 6 resonator.

Each waveguide 4 extends along a respective X-X propagation axis and includes a respective propagation zone 8 for the propagation of electromagnetic waves.

As it appears on the , the waveguides 4 are arranged around the central resonator 6, their respective axes of propagation XX extending radially from the central resonator 6, for example at 120° (Y junction) or 90° (T junction) to each other others.

The central resonator 6 and the waveguides 4 are arranged so that electromagnetic waves can circulate between a resonant volume 10 of the central resonator 6 and the propagation zone 8 of each waveguide.

The central resonator 6 has an upper wall 12 and a lower wall 14.

The central resonator 6 further comprises a first ferromagnetic element 15A and a second ferromagnetic or dielectric element 15B arranged between the upper wall 12 and the lower wall 14, as will be described below. When the second element 15B is ferromagnetic, it is preferably a ferrite.

The first ferromagnetic element 15A gives component 2 its non-reciprocity. The second ferromagnetic or dielectric element 15B allows impedance matching between the central resonator 6 and the waveguides 4, which gives component 2 a wide bandwidth.

The upper wall 12 and the lower wall 14 extend on either side of the resonance volume 10 intended for the propagation of electromagnetic waves.

Each of the upper wall 12 and the lower wall 14 comprises a respective conductive surface 24, able to conduct electricity. The conductive surface of the upper wall is called "upper conductive surface 26" and the conductive surface of the lower wall is called "lower conductive surface 28".

The upper conductive surface 26 extends facing the lower conductive surface 28, the upper 26 and lower 28 conductive surfaces being arranged at a distance from each other, and each being oriented towards the resonance volume 10. For example , the upper 26 and lower 28 conductive surfaces are separated by a dielectric insulating thickness 25, for example air or vacuum.

By way of example, at least one of the upper wall 12 and the lower wall 14 is a substrate conventionally used in electronics. In known manner, such a substrate comprises a dielectric plate 16, made of at least one dielectric material. Furthermore, as shown in the , such a dielectric plate 16 has an inner face 20 covered by a conductive layer which forms the conductive surface 24.

Such substrates are also likely to be used to produce the waveguides 4, according to the known principles of SIW components (from the English “ Substrate Integrated Waveguide ”, or waveguide integrated into the substrate) or the AFSIW ( Air-Filled Substrate Integrated Waveguide ) technology or ESIW ( Empty Substart Integrated Waveguide ) technology. For example :
- the waveguide 4 is delimited, in a direction ZZ orthogonal to the walls 12, 14, by the conductive surfaces 24, and, in a direction orthogonal to the direction ZZ and to the axis of propagation XX, by metal vias extending between said conductive surfaces, through additional substrates arranged between the conductive surfaces 24; Or
- the waveguide 4 is delimited, along the orthogonal direction ZZ, by the conductive surfaces 24, and, along the direction orthogonal to the direction ZZ and to the axis of propagation XX, by metallized slices of additional substrates arranged between conductive surfaces 24.

Alternatively, at least one of the upper wall 12 and the lower wall 14 is entirely made of an electrically conductive material, for example machined to have the desired dimensions.

As previously indicated, the first ferromagnetic element 15A gives component 2 its non-reciprocity, once it has been magnetized. In addition, the ferromagnetic or dielectric element 15B makes it possible to achieve impedance matching between the waveguides 4 and the central resonator 6.

The first ferromagnetic element 15A and the second ferromagnetic or dielectric element 15B are arranged in the resonance volume 10, and are stepped along a direction Z-Z orthogonal to the walls 12, 14, the first ferromagnetic element 15A and the second ferromagnetic or dielectric element 15B being separated by a dielectric layer 30. The dielectric layer 30 is a gas or vacuum layer or a solid layer such as an organic substrate or a ceramic.

In addition, the first ferromagnetic element 15A is in contact with the upper conductive surface 26, and the second ferromagnetic or dielectric element 15B is in contact with the lower conductive surface 28.

These first and second elements 15A and 15B differ from each other. Advantageously, the first ferromagnetic element 15A and the second ferromagnetic or dielectric element 15B differ by their shapes and/or by the materials from which they are made.

Depending on the desired characteristics of component 2, the respective shapes of elements 15A and 15B are likely to be adjusted. More specifically, each element 15A or 15B is capable of having any shape leading to desired performance of component 2, in particular satisfactory impedance matching between central resonator 6 and waveguides 4, or even reflection coefficients and/or transmission whose respective values belong to desired working ranges. For example, each element 15A or 15B has the shape of a cylinder, prism, sphere, etc.

In addition, the elements 15A and 15B may be made of different materials, in order to give the component 2 the desired characteristics. In particular, these shapes and materials are chosen to achieve satisfactory impedance matching between the waveguides 4 and the central resonator 6.

Preferably, the ferromagnetic element 15A, and the element 15B when it is ferromagnetic, are made of an anisotropic material, such as a soft magnetic material, for example a soft ferrite magnetized by means of an external permanent magnet.

Preferably again, the ferromagnetic element 15A, and the element 15B when it is ferromagnetic, are made of ferrite of high anisotropy, for example a hexagonal ferrite, commonly called “hexaferrite”. The use of such a material is advantageous insofar as it makes superfluous the application, during the operation of component 2, of an external magnetic field intended to polarize said ferromagnetic elements. Indeed, a highly anisotropic ferromagnetic ceramic element, in particular hexaferrite, has the property of retaining its magnetization once subjected to a magnetic field.

Alternatively, element 15B is a dielectric.

FIGS. 3, 4 and 5 illustrate an example of evolution of the transmission coefficient S ₂₁ , of the reflection coefficient S ₁₁ and of the insulation coefficient S ₁₂ , respectively, of the non-reciprocal microwave component according to the invention, in depending on the frequency. The non-reciprocal microwave component has good electromagnetic performance over a wide frequency band.

In the frequency band between 13 and 25 GHz, it can be seen that the transmission coefficient S ₂₁ is substantially constant between the frequencies 17.3 GHz and 21.5 GHz.

Between these same frequencies 17.3 GHz and 21.5 GHz, the reflection coefficient S ₁₁ and the insulation coefficient S ₁₂ have minimum values.

Claims (7)

Non-reciprocal microwave component (2) comprising at least three waveguides (4) and a central resonator (6),
the central resonator comprising an upper wall (12) and a lower wall (14) extending on either side of a resonance volume (10) for the propagation of electromagnetic waves,
each waveguide extending along a respective propagation axis (XX), each waveguide comprising a propagation zone for the propagation of electromagnetic waves,
the central resonator and each waveguide being arranged so that electromagnetic waves can circulate between the resonant volume of the central resonator and the propagation zone of each waveguide,
the non-reciprocal microwave component (2) being characterized in that the upper wall, respectively the lower wall, comprises an upper conductive surface (26), respectively a lower conductive surface (28), oriented towards the resonance volume, the upper conductive surface extending opposite the lower conductive surface,
the central resonator further comprising a first ferromagnetic element (15A) and a second ferromagnetic or dielectric element (15B),
the first ferromagnetic element and the second ferromagnetic or dielectric element being arranged in the resonance volume, and being stepped in a direction orthogonal to the upper wall, being separated by a dielectric layer (30),
the first ferromagnetic element being in contact with the upper conductive surface and the second ferromagnetic or dielectric element being in contact with the lower conductive surface. Non-reciprocal microwave component according to Claim 1, in which the first element (15A) and the second element (15B) differ in their shapes and/or in the materials in which they are made. Non-reciprocal microwave component according to claim 1 or 2, wherein the top wall and/or the bottom wall is a substrate having a metallized face, the metallized face forming the corresponding one of the upper conductive surface and the lower conductive surface . Non-reciprocal microwave component according to any one of Claims 1 to 3, in which the first ferromagnetic element (15A) and/or the second element (15B) when it is ferromagnetic is made of ferrite, for example a hexagonal ferrite . Non-reciprocal microwave component according to any one of Claims 1 to 4, in which the first ferromagnetic element (15A) and/or the second element (15B) when it is ferromagnetic is made of an anisotropic material, preferably a hexagonal ferrite. A non-reciprocal microwave component according to any of claims 1 to 5, wherein the dielectric layer (30) is a gas or vacuum layer or a solid layer. On-board radio frequency system comprising at least one non-reciprocal microwave component according to any one of claims 1 to 6.