Tunable impedance matching network

What is claimed is: 1. An impedance matching network having a first impedance matching terminal and a second impedance matching terminal, the impedance matching network comprising: a first parallel reactive network connected to the first impedance matching terminal of the impedance matching network, the first parallel reactive network comprising a plurality of parallel branches each connected the first impedance matching terminal and a reference potential, each parallel branch comprising one or more reactive elements connected in series, wherein one parallel branch from among the plurality of parallel branches comprises two series—connected elements; a series reactive network having a first terminal and a second terminal, the series reactive network comprising at least an inductor, the first terminal of the series reactive network being connected to a node joining the two series—connected elements of the one parallel branch of the first parallel reactive network; and a second parallel reactive network connected to the second impedance matching terminal of the impedance matching network, the second parallel reactive network comprising a plurality of parallel branches each connected between the second impedance matching terminal and the reference potential, each parallel branch comprising one or more reactive elements connected in series, the second parallel reactive network being connected at a node to both the second impedance matching terminal and to the second terminal of the series reactive network, wherein the impedance matching network is configured to match an impedance at the first impedance matching terminal of the impedance matching network to a variable impedance at the second impedance matching terminal of the impedance matching network, and wherein the second parallel reactive network is configured to provide a harmonic termination. 2. A circuital arrangement comprising: a scalable periphery power amplifier; and the impedance matching network of claim 1 connected to the scalable periphery power amplifier. 3. The circuital arrangement of claim 2 , wherein the scalable periphery amplifier is adapted, during operation, to amplify a first signal characterized by a first signal power level to produce a second signal that is an amplified version of the first signal, the scalable periphery amplifier comprising: one or more unit cells, each unit cell being adapted to be selectively activated or deactivated, wherein each such unit cell comprises one or more active devices configured to operate as an amplifier; and an amplifier control circuitry that is configured to selectively activate or deactivate the one or more unit cells in response to changing input signal power level to tune total current output from the scalable periphery amplifier, wherein an output of the scalable periphery amplifier is connected to the second impedance matching terminal of the impedance matching network. 4. The circuital arrangement according to claim 3 , wherein the impedance matching network is configured to match a variable impedance of the output of the scalable periphery amplifier connected to the second impedance matching terminal to a fixed impedance at the first impedance matching terminal. 5. The circuital arrangement of claim 4 , wherein the amplifier control circuitry is further configured to tune the impedance matching network for a desired transfer of an output power at the output of the scalable periphery amplifier to the first impedance matching terminal of the impedance matching network. 6. The circuital arrangement according to claim 4 , wherein during operation of the circuital arrangement, a varying value of the variable impedance is higher and lower than a fixed value of the fixed impedance. 7. The circuital arrangement of claim 3 , wherein tunable capacitors of the impedance matching network are monolithically integrated on a chip with the one or more unit amplifier of the scalable periphery amplifier using silicon on insulator or silicon on sapphire technology. 8. The circuital arrangement of claim 3 , wherein the circuital arrangement is monolithically integrated. 9. The impedance matching network of claim 1 , wherein: a first parallel branch from among the plurality of parallel branches of the first parallel reactive network comprises a first tunable capacitor; a second parallel branch from among the plurality of parallel branches of the first parallel reactive network comprises an inductor; the two series-connected elements of the one parallel branch are a series-connected first capacitor and second tunable capacitor, respectively; a first parallel branch from among the plurality of parallel branches of the second parallel reactive network comprises an inductor; a second parallel branch from among the plurality of parallel branches of the second parallel reactive network comprises a third tunable capacitor; and a second capacitor serially-connected with both the first parallel branch and the second parallel branch of the second parallel reactive network. 10. The impedance matching network of claim 9 , wherein the series reactive network is devoid of tunable capacitors. 11. The impedance matching network of claim 10 , being configured to match the variable impedance at the second impedance matching terminal to a fixed impedance at the first impedance matching terminal. 12. The impedance matching network of claim 10 , wherein the impedance matching network is devoid of tunable inductors. 13. The impedance matching network of claim 9 , wherein one or more of: a) the first tunable capacitor, b) the second tunable capacitor, and c) the third tunable capacitor, is a digitally tunable capacitor (DTC). 14. The impedance matching network of claim 1 , wherein: a first parallel branch from among the plurality of parallel branches of the second parallel reactive network comprises an inductor; a second parallel branch from among the plurality of parallel branches of the second parallel reactive network comprises a third tunable capacitor; and a second capacitor serially-connected with both the first parallel branch and the second parallel branch of the second parallel reactive network. 15. The impedance matching network of claim 14 , wherein the series-connected second capacitor is a tunable capacitor. 16. The impedance matching network of claim 1 , being configured to match the variable impedance at the second impedance matching terminal to a fixed impedance at the first impedance matching terminal over a frequency range of operation. 17. The impedance matching network of claim 16 , wherein the fixed impedance is 50Ω. 18. The impedance matching network of claim 1 , wherein: a first parallel branch from among the plurality of parallel branches of the first parallel reactive network comprises a first tunable capacitor; a second parallel branch from among the plurality of parallel branches of the first parallel reactive network comprises an inductor; and the two series-connected elements of the one parallel branch are a series-connected first capacitor and second tunable capacitor, respectively. 19. The impedance matching network of claim 1 , the impedance matching network is devoid of tunable inductors. 20. The impedance matching network of claim 1 , wherein: a first parallel branch from among the plurality of parallel branches of the first parallel reactive network comprises a first tunable capacitor; a second parallel branch from among the plurality of parallel branches of the first parallel reac