Harmonic trap filter using coupled resonators

The invention claimed is: 1. A harmonic trap filter to suppress at least one harmonic signal produced by an amplifier, the harmonic trap filter comprising: an input terminal and a ground terminal; and a plurality of resonators electrically coupled one to another between the input terminal and the ground terminal in a spatial order defined by relative phase shift of alternating voltage bias signals respectively applied thereto, the resonators being tuned to resonate at at least one frequency at which a phase delay is imparted to the at least one harmonic signal by the resonators to effect cancelation of the at least one harmonic signal at the input terminal. 2. The harmonic trap filter of claim 1 , wherein the resonators are electrically coupled into isolator circuits connected in series to define at least one non-reciprocal electrical path that begins and ends at the input terminal. 3. The harmonic trap filter of claim 2 , wherein the series-connected isolator circuits are series-connected circulators. 4. The harmonic trap filter of claim 3 , wherein a first circulator of the series-connected circulators is electrically coupled in series with a second circulator of the series-connected circulators, where an input port of the first circulator and an output port of the second circulator are electrically coupled to the input terminal. 5. The harmonic trap filter of claim 2 , wherein the relative phase shift applied to the resonators of each isolator circuit is a predetermined phase angle apart. 6. The harmonic trap filter of claim 5 , wherein the predetermined phase angle is 120°. 7. The harmonic trap filter of claim 2 , wherein the resonators electrically coupled into isolator circuits connected in series define respective non-reciprocal electrical paths that begin and end at the input terminal, the isolator circuits in each non-reciprocal electrical path being tuned to resonate at a frequency that is different from a frequency at which the isolator circuits in other non-reciprocal electrical paths resonate. 8. The harmonic trap filter of claim 1 , further comprising: control circuitry to generate control signals, wherein the resonators each comprise a variable capacitive element by which resonance of the corresponding resonator is tuned, the capacitance of each variable capacitive element being established by a corresponding one of the control signals applied thereto by the control circuitry. 9. The harmonic trap filter of claim 8 , wherein the control circuitry is configured to generate the control signals to vary over time such that the frequency at which the phase delay is imparted to the at least one harmonic signal varies in accordance with a frequency modulated signal applied to the input terminal. 10. A radio-frequency (RF) transmitter comprising: an amplifier; and a harmonic trap filter to suppress at least one harmonic signal produced by the amplifier, the harmonic trap filter comprising: an input terminal and a ground terminal; and a plurality of resonators electrically coupled one to another between the input terminal and the ground terminal in a spatial order defined by relative phase shift of alternating voltage bias signals respectively applied thereto, the resonators being tuned to resonate at at least one frequency at which a phase delay is imparted to the at least one harmonic signal by the resonators to effect cancelation of the at least one harmonic signal at the input terminal. 11. The RF transmitter of claim 10 , wherein the resonators are electrically coupled into isolator circuits connected in series to define at least one non-reciprocal electrical path that begins and ends at the input terminal. 12. The RF transmitter of claim 11 , wherein the series-connected isolator circuits are series-connected circulators. 13. The RF transmitter of claim 12 , wherein a first circulator of the series-connected circulators is electrically coupled in series with a second circulator of the series-connected circulators, where an input port of the first circulator and an output port of the second circulator are electrically coupled to the input terminal. 14. The RF transmitter of claim 11 , wherein the relative phase shift applied to the resonators of each isolator circuit is a predetermined phase angle apart. 15. The RF transmitter of claim 14 , wherein the predetermined phase angle is 120°. 16. The RF transmitter of claim 11 , wherein the resonators electrically coupled into isolator circuits connected in series define respective non-reciprocal electrical paths that begin and end at the input terminal, the isolator circuits in each non-reciprocal electrical path being tuned to resonate at a frequency that is different from a frequency at which the isolator circuits in other non-reciprocal electrical paths resonate. 17. The RF transmitter of claim 10 , further comprising: control circuitry to generate control signals, wherein the resonators each comprise a variable capacitive element by which resonance of the corresponding resonator is tuned, the capacitance of each variable capacitive element being established by a corresponding one of the control signals applied thereto by the control circuitry. 18. The RF transmitter of claim 17 , wherein the control circuitry is configured to generate the control signals to vary over time such that the frequency at which the phase delay is imparted to the at least one harmonic signal varies in accordance with a frequency modulated signal applied to the input terminal. 19. A shunt harmonic trap filter comprising: an input terminal; and a first magnet-free isolator circuit and a second magnet-free isolator circuit electrically coupled in series with the first magnet-free isolator circuit to define a non-reciprocal circuit path that begins and ends at the input terminal, wherein each of the first magnet-free isolator circuit and the second magnet-free isolator circuit comprise a plurality of resonators, each being tuned to resonate at a frequency at which a phase delay is imparted to a harmonic signal by the first and second magnet-free isolator circuits to effect cancelation of the harmonic signal at the input terminal.