Tunable microwave system

The invention claimed is: 1. A tunable microwave system comprising at least two elements, each element being chosen from a propagating guide (GPE, GPS, GP 1 , GP 2 ), an evanescent guide (EG 1 i , EG 2 i ), a resonator (Res 1 , Res 2 , Resi, Res), and at least one coupling device (CD) arranged between the two elements and configured to couple the two elements to each other, said coupling device (CD, CDi, CDE, CDS, CDL 1 i , CDL 2 i , CDij) comprising a holder (Sp) having an aperture (Ap) and comprising at least one elongate element the shape of which is elongate in a direction called the polarization direction (Dp) contained in a plane (P) of the aperture, said elongate element being securely fastened to the perimeter of the aperture at at least one end, said coupling device being configured to be rotatable about an axis substantially perpendicular to said plane of the aperture so as to modify a value of the polarization direction (Dp) and so that the coupling between the two elements is dependent on said value of the polarization direction. 2. The system as claimed in claim 1 , wherein the coupling device (CD) comprises a plurality of elongate elements parallel to one another. 3. The system as claimed in claim 2 , wherein the elongate elements form a grid (Gri) in the aperture (Ap). 4. The system as claimed in claim 1 , wherein the one or more elongate elements are wire, bar or strip shaped. 5. The system as claimed in claim 1 , wherein the aperture (Ap) is circular or oval in shape. 6. The system as claimed in claim 1 , wherein the one or more elongate elements are made of a metallized dielectric material or metal material, and are electrically connected to one another by a metal contact arranged on the perimeter of the aperture. 7. The system as claimed in claim 1 , wherein the holder (Sp) takes the form of a circular disk configured to be rotated manually or using a micro stepper motor. 8. The system as claimed in claim 1 , wherein at least one portion of the holder (Sp) is made of dielectric material. 9. The system as claimed in claim 1 , comprising n successive resonators (Resi) indexed i, i varying from 1 to n, n being higher than or equal to 2, the resonator indexed 1 (Res 1 ) being called the input resonator and the resonator indexed n (Resn) being called the output resonator, wherein two successive resonators i and i+1 are coupled to each other by an associated coupling device (CDi), the system performing a tunable n-pole filter function. 10. The system as claimed in claim 9 , furthermore comprising an input coupling device (CDE) configured to couple an input propagating guide (GPE) to the input resonator (Res 1 ) and an output coupling device (CDS) configured to couple the output resonator (Resn) to an output propagating guide (GPS). 11. The system as claimed in claim 1 , comprising a resonator (Res) and a first evanescent guide (EG 1 ) arranged laterally with respect to said resonator (Res) with respect to a direction (z) of propagation of a microwave through the system, the associated coupling device arranged between the resonator and the first evanescent guide being called the first lateral coupling device (CDL 1 ), and being configured to produce a variation in a resonant frequency of said resonator as a function of the polarization direction (Dp). 12. The system as claimed in claim 11 , furthermore comprising a second evanescent guide (EG 2 ) arranged on the opposite side to the first evanescent guide, the associated coupling device arranged between the resonator and the second evanescent guide being called the second lateral coupling device (CDL 2 ), the first and second lateral coupling devices being configured to have an identical polarization direction. 13. The system as claimed in claim 1 , comprising n resonators (Resi) indexed i, i varying from 1 to n, n being higher than or equal to 2, the resonator indexed 1 (Res 1 ) being called the input resonator and the resonator indexed n (Resn) being called the output resonator, wherein two successive resonators i and i+1 are coupled to each other by an associated coupling device (CDi), and wherein at least one resonator i (Resi) is moreover coupled to a first evanescent guide (EG 1 i ) by a first lateral coupling device (CDL 1 i ) and, where appropriate, to a second evanescent guide (EG 2 i ) by a second lateral coupling device (CDL 2 i ), the first and, where appropriate, the second evanescent guide being arranged laterally with respect to said resonator (Resi) with respect to a direction (z) of propagation of a microwave through the system. 14. The system as claimed in claim 13 , furthermore comprising an input coupling device (CDE) configured to couple an input propagating guide (GPE) to the input resonator (Res 1 ) and an output coupling device (CDS) configured to couple the output resonator (Resn) to an output propagating guide (GPS). 15. The system as claimed in claim 13 , wherein the n resonators are configured so that a resonator i is furthermore coupled to a resonator j different from i+1 with an associated coupling device (CDij) arranged between the resonator i and the resonator j. 16. The system as claimed in claim 15 , wherein the coupling device (CDij) arranged between the resonator i and the resonator j is configured to create inter-resonator interference effects that allow transmission zeros to be added to the transmission of the tunable filter. 17. The system as claimed in claim 15 , wherein the coupling device between the resonator i and the resonator i+1 (CDi) and the coupling device between the resonator j−1 and the resonator j (CDj−1) are configured so that the coupling between said resonators drops each to zero for a set value of the polarization direction, so that the filter has a number of reconfigurable poles. 18. The system as claimed in claim 1 , comprising two contiguous propagating guides coupled to each other by an associated coupling device configured so that the coupling between said propagating guides drops to zero for a set value of the polarization direction. 19. The system as claimed in claim 1 , comprising two propagating guides parallel to each other, wherein the associated coupling device is arranged in a wall common to the two guides and is configured to achieve a transfer of a microwave propagating through one of the guides propagating to the other guide, said transfer being dependent on the value of the polarization direction.