Resonant circuit with variable frequency and impedance

The invention claimed is: 1. A resonant circuit with a characteristic impedance stabilized at a chosen value, comprising an input terminal and an output terminal, and at least: a group of N resonators, where N>1, said group of N resonators having a same resonance frequency and a same antiresonance frequency; the group of N resonators configured to provide a variable static capacitance; a first impedance matching element and a second impedance matching element having a non-zero reactance, the first impedance matching element being in series with said group of N resonators, and the second impedance matching element being in parallel with said group of N resonators, said resonant circuit comprising: first means for controlling said group of N resonators, enabling a static capacitance of said group of N resonators to be fixed at a first value; second control means, enabling the impedance of the first impedance matching element and that of the second impedance matching element to be fixed at second values; said first and second values being such that: a triplet of values composed of the static capacitance of said group of N resonators, the impedance of the first impedance matching element, and the impedance of the second impedance matching element being used to determine the following triplet of parameters: the characteristic impedance Z c of an assembly formed by said group of N resonators, said first impedance matching element and said second matching element; the resonance frequency ω r of said assembly formed by said group of N resonators, said first impedance matching element and said second matching element; the antiresonance frequency ω a of said assembly formed by said group of N resonators, said first impedance matching element and said second matching element, in order to stabilize the impedance of said circuit at a chosen characteristic impedance. 2. The resonant circuit according to claim 1 , wherein: said group of N resonators consists of a plurality of resonators: said first control means comprising a switching circuit for selecting and connecting one or more resonators. 3. The resonant circuit according to claim 2 , wherein the resonators are bulk acoustic wave resonators which may have different geometrical dimensions. 4. The resonant circuit according to claim 2 , wherein the resonators are surface acoustic wave resonators which may have different arrangements of electrodes on the surface of a piezoelectric substrate. 5. The resonant circuit according to claim 1 , wherein: said resonator has a variable capacitance whose value is a function of the value of an electrical control signal; said first means comprising means for causing said electrical control signal to vary. 6. The resonant circuit according to claim 5 , wherein said resonator is an electrostrictive resonator based on BST material. 7. The resonant circuit according to claim 1 , wherein at least one impedance matching element is a capacitor, an inductance or a set of passive elements. 8. The resonant circuit according to claim 1 , wherein at least one impedance matching element is an active circuit. 9. The resonant circuit according to claim 8 , wherein the active circuit comprises transistors. 10. The resonant circuit according to claim 1 , wherein the second impedance matching element is connected, on the one hand, to one of the input/output terminals, and on the other hand to an intermediate node between the group of resonators and said first impedance matching element. 11. The resonant circuit according to claim 1 , wherein the second impedance matching element is placed between the input and output terminals, fitted in parallel with the assembly composed of the group of resonators and the first impedance matching element, placed in series. 12. The resonant circuit according claim 1 , comprising: a first chip comprising at least said first control means for fixing the static capacitance of said group of resonators at a first value; a second chip comprising said group of resonators; means for the interconnection of said first control means with said group of resonators. 13. The resonant circuit according to claim 12 , wherein the first chip also comprises the first and second impedance matching elements. 14. The resonant circuit according to claim 12 , wherein the second chip also comprises the first and second impedance matching elements. 15. A filter comprising a set of resonant circuits according to claim 1 . 16. A duplexer comprising a set of resonant circuits according to claim 1 . 17. A device comprising a set of at least two resonant circuits according to claim 1 and having an input impedance and an output impedance, contained between an input port and an output port, comprising first means for controlling the group of resonators and second means for controlling the first and second impedance matching elements, for adjusting: the characteristic impedance of each of said circuits; the resonance and antiresonance frequencies of each of said circuits. 18. The device comprising a set of at least two resonant circuits according to claim 1 , wherein said first means for controlling the group of resonators and said second means for controlling the first and second impedance matching elements cause variations of the triplets of values composed of the static capacitance of said group, the impedance of the first impedance matching element, and the impedance of the second impedance matching element, for the purpose of: adjusting the values of characteristic impedance of the two resonant circuits to fixed values; causing the resonance and antiresonance frequencies of the two resonant circuits to vary. 19. The device comprising a set of at least two resonant circuits according to claim 1 , wherein said first means for controlling the group of resonators and said second means for controlling the first and second impedance matching elements cause variations of the triplets of values composed of the static capacitance of said group, the impedance of the first impedance matching element, and the impedance of the second impedance matching element, for the purpose of: causing the values of characteristic impedance of the two resonant circuits to vary; adjusting the resonance and antiresonance frequencies of the two resonant circuits to fixed values. 20. A resonant circuit with a characteristic impedance stabilized at a chosen value, comprising an input terminal and an output terminal, and at least: a group of N resonators, where N said group of N resonators having a same resonance frequency and a same antiresonance frequency; a first impedance matching element and a second impedance matching element having a non-zero reactance, the first impedance matching element being in series with said group of N resonators, and the second impedance matching element being in parallel with said group of N resonators, said resonant circuit comprising: first means for controlling said group of N resonators, enabling a static capacitance of said group of N resonators to be fixed at a first value; second control means, enabling the impedance of the first impedance matching element and that of the second impedance matching element to be fixed at second values; said first and second values being such that: a triplet of values composed of the static capacitance of said group of N resonators, the impedance of the first impedance matching element, and the impedance of the second impedance matching element being used t