Superconducting phase-shift system

What is claimed is: 1. A superconducting phase-shift system comprising: an all-pass filter comprising at least one variable inductance element comprising at least one Superconducting Quantum Interference Device (SQUID), the all-pass filter being configured to receive an input signal and to provide the input signal as an output signal that is phase-shifted relative to the input signal based on a variable inductance provided by each of the at least one variable inductance element; and a phase controller configured to provide a phase-control current to control the variable inductance of the at least one variable inductance element based on a characteristic of the phase-control current. 2. The system of claim 1 , wherein the at least one variable inductance element is configured as a flux-controlled variable inductor that provides the variable inductance as a function of magnetic flux based on an amplitude of the phase-control current. 3. The system of claim 1 , wherein the at least one SQUID comprises a parallel pair of Josephson junctions that are biased based on the phase-control current via an inductive coupling. 4. The system of claim 3 , wherein the parallel pair of Josephson junctions are configured to have asymmetrical critical currents with respect to each other. 5. The system of claim 1 , wherein each of the at least one variable inductance element comprises: a first Superconducting Quantum Interference Device (SQUID) coupled to one of an input and an output of the all-pass filter and comprising a first parallel pair of Josephson junctions interconnecting the one of the input and the output and an inductive coupling to the phase-control current to provide a bias current to the first parallel pair of Josephson junctions; and a second SQUID coupled to a capacitor interconnecting the second SQUID and a low-voltage rail, the second SQUID comprising a second parallel pair of Josephson junctions interconnecting the capacitor and an inductive coupling to the phase-control current to provide a bias current to the second parallel pair of Josephson junctions, wherein the first SQUID and the second SQUID are connected in series via the inductive couplings. 6. The system of claim 5 , wherein the first and second parallel pairs of Josephson junctions each have asymmetrical critical currents with respect to each other. 7. The system of claim 5 , wherein the at least one variable inductance element comprises: a first variable inductance element that interconnects an input of the all-pass filter and a first capacitor that is coupled to a low-voltage rail; and a second variable inductance element that interconnects an output of the all-pass filter and the first capacitor, wherein the input and the output are separated by a second capacitor across which the input signal is provided as the output signal. 8. The system of claim 1 , wherein each of the at least one variable inductance element comprises a plurality of variable inductance portions in a cascaded arrangement between one of an input and an output of the all-pass filter and a capacitor that is coupled to a low-voltage rail, wherein each of the plurality of variable inductance portions provides a separate and independent contribution to the variable inductance in response to an amplitude of a respective one of a plurality of phase-control currents provided from the phase controller. 9. The system of claim 1 , wherein the all pass-filter element is a first all-pass filter configured to provide a first phase-shift of the input signal, the system further comprising at least one additional all-pass filter coupled in series to the first all-pass filter, each of the at least one additional all-pass filter comprising at least one variable inductance element and being configured to provide additional phase-shift of the input signal in providing the output signal based on a variable inductance provided by each of the at least one variable inductance element. 10. A superconducting phase-shift system comprising: an all-pass filter comprising at least one variable inductance element, the all-pass filter being configured to receive an input signal and to provide the input signal as an output signal that is phase-shifted relative to the input signal based on a variable inductance provided by each of the at least one variable inductance element, wherein the at least one variable inductance element comprises: a first variable inductance element that interconnects an input of the all-pass filter and a first capacitor that is coupled to a low-voltage rail; and a second variable inductance element that interconnects an output of the all-pass filter and the first capacitor, wherein the input and the output are separated by a second capacitor across which the input signal is provided as the output signal; and a phase controller configured to provide a phase-control current to control the variable inductance of the at least one variable inductance element based on a characteristic of the phase-control current. 11. The system of claim 10 , wherein each of the first and second variable inductance elements comprises an inductive coupling to receive the phase-control current to provide an approximately equal variable inductance with respect to each other. 12. A method for phase-shifting an input signal via an all-pass filter, the method comprising: receiving the input signal at an input of the all-pass filter; providing a phase-control current from a phase controller onto a control line that is inductively coupled to a first variable inductance element that is coupled to the input and to a second variable inductance element that is coupled to an output of the all-pass filter; adjusting an amplitude of the phase-control current to control a variable inductance associated with each of the first and second variable inductance elements; and providing an output signal at the output that is phase-shifted relative to the input signal based on the variable inductance of the first and second variable inductance elements. 13. The method of claim 12 , wherein each of the first and second variable inductance elements comprises at least one Superconducting Quantum Interference Device (SQUID) comprising a parallel pair of Josephson junctions, wherein providing the phase-control current comprises providing the phase-control current onto the control line to induce a magnetic flux in the SQUID. 14. The method of claim 13 , wherein the parallel pair of Josephson junctions are configured to have asymmetrical critical currents with respect to each other. 15. The method of claim 12 , wherein providing the phase-control current comprises providing the phase-control current from a phase controller onto a control line that is inductively coupled to a first Superconducting Quantum Interference Device (SQUID) that is coupled to the input and to a second SQUID that is coupled to the output, wherein each of the first SQUID and the second SQUID comprises a parallel pair of Josephson junctions that are biased by the phase-control current. 16. The method of claim 12 , wherein providing the phase-control current comprises providing a plurality of phase-control currents to a each of a first respective plurality of variable inductance portions in a cascaded arrangement between the input and a capacitor that is coupled to a low-voltage rail and to each of a second respective plurality of variable inductance portions in a cascaded arrangement between the output and the capacitor, wherein each of the first and second pluralities of variable inductance portions provides a separate and independent contribution to