Multi-qubit entangling gate using a frequency-modulated tunable coupler

What is claimed is: 1. A method of operating a quantum processing device comprising a frequency-tunable coupler and n fixed-frequency quantum circuits of distinct frequencies, n≥3, each of the quantum circuits coupled to the tunable coupler, wherein a frequency of the tunable coupler can be concomitantly modulated at m frequencies, wherein m≥2, and wherein said m frequencies correspond, each, to a difference of energy between a respective pair of quantum states spanned by the quantum circuits, the method comprising: modulating the frequency of the tunable coupler concomitantly at said m frequencies, so as to drive m energy transitions between connected pairs of states spanned by the quantum circuits and achieve an entangled state of the quantum circuits as a superposition of l states spanned by the quantum circuits, where l≥m. 2. The method according to claim 1 , wherein the number m of frequencies used to concomitantly modulate the tunable coupler is less than or equal to C(C(n, k), 2), for a given value of k, where n−1≥k≥1 and C(n, k) denotes a binomial coefficient ( k n ). 3. The method according to claim 2 , wherein the number m of frequencies used to concomitantly modulate the tunable coupler is less than or equal to C(n, k), for a given value of k, where n−1≥k≥1. 4. The method according to claim 3 , wherein the frequency of the tunable coupler is concomitantly modulated at m=C(n, k) frequencies, for said given value of k. 5. The method according to claim 4 , wherein the frequency of the tunable coupler is concomitantly modulated at said m frequencies during a period of time such as to achieve an entangled state as a superposition of l=m=C(n, k) states spanned by the quantum circuits. 6. The method according to claim 3 , wherein: the states of said connected pairs of states are, each, representable as tensor products of individual states |a™ of the quantum circuits, and said m frequencies are such that each of the driven energy transitions involves exactly two parallel transitions between individual states |a™ of the quantum circuits. 7. The method according to claim 2 , wherein the states of said connected pairs of states are, each, representable as tensor products of individual states |a™ of the quantum circuits, and said m frequencies are such that each of the driven energy transitions involves anti-parallel transitions between individual states |a™ of the quantum circuits. 8. The method according to claim 7 , wherein: the number m of frequencies used to concomitantly modulate the tunable coupler is equal to C(C(n, k), 2), for said given value of k. 9. The method according to claim 1 , wherein the states of said connected pairs of states are, each, representable as tensor products of individual states |a™ of the quantum circuits, and said m frequencies are such that some of the driven energy transitions involve parallel transitions between individual states |a™ of the quantum circuits, whereas other ones of the driven energy transitions involve anti-parallel transitions between such individual states |a™. 10. The method according to claim 1 , wherein the m energy transitions are driven by applying harmonic microwave signals to the tunable coupler, the signals modulated so as to modulate the frequency of the tunable coupler at said m frequencies. 11. The method according to claim 10 , further comprising setting amplitudes, phases and durations of the signals applied to the tunable coupler, so as to control amplitudes and phases of coefficients a i weighting the l states spanned by the quantum circuits in the entangled state achieved. 12. A quantum processing device, comprising: n fixed-frequency quantum circuits of distinct frequencies, n≥3; a frequency-tunable coupler, to which the n quantum circuits are coupled, the coupler configured so that a frequency of the coupler can be concomitantly modulated at m frequencies, m≥2, wherein said m frequencies correspond, each, to a difference of energy between a respective pair of quantum states spanned by the quantum circuits; and a controller, configured in the quantum processing device to modulate the frequency of the tunable coupler concomitantly at said m frequencies, so as to drive m energy transitions between connected pairs of states spanned by the quantum circuits and achieve an entangled state of the quantum circuits as a superposition of l states spanned by the quantum circuits, where l≥m. 13. The quantum processing device according to claim 12 , wherein each of said quantum circuits is a superconducting quantum circuit. 14. The quantum processing device according to claim 12 , wherein each of said quantum circuits is a fixed-frequency, transmon-type quantum circuit. 15. The quantum processing device according to claim 12 , wherein the tunable coupler is capacitively coupled to each of the quantum circuits. 16. The quantum processing device according to claim 12 , wherein the controller is further configured to apply harmonic microwave signals to the tunable coupler and modulate the signals applied so as to modulate the frequency of the tunable coupler at said m frequencies. 17. The quantum processing device according to claim 13 , wherein the controller is further configured to allow setting amplitudes, phases and durations of the signals applied to the tunable coupler, so as to control amplitudes and phases of coefficients a i weighting the l states spanned by the quantum circuits in the entangled state to be achieved. 18. A quantum processing chip, comprising a plurality of cells, each comprising: n fixed-frequency quantum circuits of distinct frequencies, n≥3; and a frequency-tunable coupler, to which the n quantum circuits are coupled, the coupler configured so that a frequency of the coupler can be concomitantly modulated at m frequencies, m≥2, wherein said m frequencies correspond, each, to a difference of energy between a respective pair of quantum states spanned by the quantum circuits, and a controller system, the latter configured in the quantum processing chip to concomitantly modulate a frequency of signals applied to the tunable coupler of each of the cells, at m frequencies, so as to drive m energy transitions between connected pairs of states spanned by the quantum circuits in selected ones of the cells, whereby, for each of said selected ones of the cells, an entangled state of the quantum circuits can be achieved as a superposition of l states spanned by the quantum circuits, where l≥m, in operation of the chip.