Circularly polarized transceiver for magnetic resonance imaging

The invention claimed is: 1. A patch resonator for nuclear magnetic resonance device comprising: a ground plane; a conductive element; a first dielectric element positioned between the ground plane and the conductive element, the resonator being configured to transmit a circularly polarized radiofrequency signal when the resonator is supplied by a first transmission line connected to the conductive element via a first connection point and configured to receive alternatively a radiofrequency signal circularly polarized in the opposite direction when the resonator is connected to a second transmission line via a second connection point, and a switch mounted in parallel on each transmission line at a distance from the ground plane corresponding to (2n+1)λ/4 with n a natural integer, and λ the wavelength of a guided wave in the transmission line at the operating frequency of the resonator, the switch making it possible to electrically connect/disconnect the first and second transmission lines from the conductive element. 2. The patch resonator for nuclear magnetic resonance device according to claim 1 , wherein the switch is a PIN diode having an off state and an on state, the PIN diode associated with the first transmission line being off during transmission and on during reception, the PIN diode associated with the second reception transmission line being on during transmission and off during reception. 3. The patch resonator for nuclear magnetic resonance device according to claim 1 , wherein the resonator has a shielding. 4. The patch resonator for nuclear magnetic resonance device according to claim 1 , wherein the resonator has a first upper shielding and a second lateral shielding at the level of a wafer of said resonator. 5. The patch resonator for nuclear magnetic resonance device according to claim 1 , further comprising: a second dielectric element located above the first dielectric element; a first upper shielding positioned on the upper face of the second dielectric element; a second lateral shielding at the edge of said resonator. 6. The patch resonator for nuclear magnetic resonance device according to claim 1 , further comprising four variable capacitors making it possible to adjust the operating frequency of the resonator and/or to adjust the impedance at the level of the first connection point and the second connection point at the operating frequency of the resonator, and/or to adjust the efficiency of the circular polarizations. 7. The patch resonator for nuclear magnetic resonance device according to claim 6 , wherein the two connection points are positioned at a surface of the conductive disc on two orthogonal main axes intersecting at a centre of the conductive disc, the two connection points being at an identical distance from the centre of the conductive disc. 8. The patch resonator for nuclear magnetic resonance device according to claim 7 , further comprising four variable capacitors, the variable capacitors being positioned along two orthogonal secondary axes, the secondary axes having an angular offset of 45° with respect to the main axes. 9. The patch resonator for nuclear magnetic resonance device according to claim 8 , wherein the variable capacitors are positioned at the intersections of the external edges of the appendages and the two secondary axes. 10. The patch resonator for nuclear magnetic resonance device according to claim 1 , wherein the conductive element has the shape of a disc and has a plurality of radial slits, each of the radial slits extending from an edge of the conductive disc up to a given distance from the centre of the conductive disc. 11. The patch resonator for nuclear magnetic resonance device according to claim 10 , wherein the resonator comprises eight slits. 12. The patch resonator for nuclear magnetic resonance device according to claim 1 , further comprising four appendages arranged around the conductive element and electrically connected to the conductive element forming a triplate line impedance transformer. 13. A high frequency antenna for nuclear magnetic resonance device comprising a patch resonator according to claim 1 . 14. The high frequency antenna for nuclear magnetic resonance device according to claim 13 , wherein the antenna is a multi-channel antenna comprising a plurality of linear resonators having a rectilinear radiating element and/or a plurality of loop resonators comprising a radiating element forming a loop, the radiating elements being used to transmit an excitation radiofrequency signal and/or to receive a relaxation radiofrequency signal.