Linear resonator of a high-frequency antenna for a nuclear magnetic resonance imaging apparatus

The invention claimed is: 1. A linear resonator of a high-frequency antenna capable of emitting a radiofrequency excitation signal and receiving a radiofrequency relaxation signal, said linear resonator comprising: a radiating element configured to emit a radiofrequency excitation signal and receive a radiofrequency relaxation signal, a balun circuit comprising a power supply line and two coupling lines; a substrate made of a dielectric material supporting said radiating element and in which said balun circuit is embedded; two contact points connecting said balun circuit to said radiating element, said contact points being formed by one of the ends of said coupling lines extending out of said substrate, a distance separating the two contact points being selected so as to ensure an impedance matching of said resonator; a ground plane separating said coupling lines of said radiating element. 2. The linear resonator according to claim 1 , comprising an adjuster configured to adjust a resonance matching and a resonance frequency of the resonator. 3. The linear resonator according to claim 2 , wherein said adjuster is connected to said balun circuit and is arranged at a distance from said radiating element such that an adjustment operation by an operator will not affect a matching or a tuning of said radiating element. 4. The linear resonator according to claim 2 , wherein said adjuster is formed by a π circuit that includes two variable capacitors and an inductor. 5. The linear resonator according to claim 1 , comprising a plurality of ground planes that cover each face of said substrate, said plurality of ground plane comprising a primary, upper ground plane that covers the upper part of said substrate. 6. The linear resonator according to claim 5 , wherein said radiating element is brazed or welded onto two ceramic capacitors, which are brazed or welded onto said upper ground plane. 7. The linear resonator according to claim 6 , wherein said ceramic capacitors are capacitors that feature a quality factor greater than 1000. 8. The linear resonator according to claim 6 , wherein said ceramic capacitors are made from alumina having a purity equal to at least 96% by weight. 9. The linear resonator according to claim 6 , wherein the values of said capacitors are selected such that they determine the resonance frequency of said resonator. 10. The linear resonator according to claim 6 , wherein said radiating element is formed by a conducting element with a cross section in the shape of an open U. 11. The linear resonator according to claim 6 , wherein said radiating element is formed by a conducting element with a rectangular cross section. 12. The linear resonator according to claim 5 , wherein said radiating element is formed by a track printed on a layer of dielectric substrate affixed permanently to said upper ground plane. 13. The linear resonator according to claim 12 , wherein said radiating element comprises twists at the ends thereof. 14. The linear resonator according to claim 13 , wherein the twists are shaped such that they determine the resonance frequency of said resonator. 15. A high-frequency antenna for a nuclear magnetic resonance apparatus comprising an insulating body and a plurality of linear resonators according to claim 1 , wherein said resonators are mounted detachably in housings of said insulating body of said antenna. 16. The antenna according to claim 15 , comprising a detachable crown configured to hold said resonators in position in their respective housings. 17. The antenna according to claim 15 , wherein said internal walls of said housings, with the exception of the one facing the radiating element, are metallised so as to insulate each resonator. 18. The antenna according to claim 15 , wherein said housings are dimensioned so as to create a pocket of air around each radiating element of each resonator in position inside said insulating body. 19. The antenna according to claim 15 , comprising a shield on a outer wall of said insulating body. 20. A linear resonator of a high-frequency antenna, said linear resonator comprising: a radiating element configured to emit a radiofrequency excitation signal and receive a radiofrequency relaxation signal, a balun circuit comprising a power supply line and two coupling lines; a substrate made of a dielectric material supporting said radiating element and in which said balun circuit is arranged; two contact points connecting said balun circuit to said radiating element, said two contact points being formed by an end of said coupling lines extending out of said substrate, a distance separating the two contact points being selected so as to permit an impedance matching of said resonator; and a ground plane separating said coupling lines of said radiating element.