Frequency management for quantum control

What is claimed is: 1. A system comprising: quantum control pulse generation circuitry; and a multi-tone generator circuit operable to: generate a plurality of fixed-frequency signals from a single fixed-frequency reference signal; and output the plurality of fixed-frequency signals via a corresponding plurality of output ports, wherein: each of the plurality of fixed-frequency signals is at a different one of a plurality of frequencies from a first frequency to a second frequency; the multi-tone generator circuit is operably coupled to the quantum control pulse generation circuitry; frequency spacing between frequency-adjacent signals of the plurality of fixed-frequency signals is less than or equal to a range of frequencies at which the quantum control pulse generation circuitry is configured to generate a pulse signal; and any frequency, from the first frequency to the second frequency, can be achieved by tuning of the pulse signal and mixing the pulse signal with one of the plurality of fixed-frequency signals. 2. The system of claim 1 , wherein the quantum control pulse generation circuitry is operable to: generate baseband pulses; and upconvert the baseband pulses to an intermediate frequency to generate quantum control pulses, wherein the intermediate frequency is tunable over a range at least as large as the frequency spacing. 3. The system of claim 1 , wherein the system comprises quantum control interconnect circuitry, wherein the quantum control interconnect circuitry is operably coupled to the quantum control pulse generation circuitry, and wherein the quantum control interconnect circuitry comprises: one or more first input ports for reception of quantum control pulses to be sent to one or more qubits; one or more second input ports for reception of one or more of the plurality of fixed-frequency signals from the multi-tone generator circuit; one or more first mixers for upconversion of the quantum control pulses received via the one or more first input ports using one or more of the plurality of fixed-frequency signals; and one or more first output ports configured to convey upconverted quantum control pulses from a first mixer to the one or more qubits. 4. The system of claim 3 , comprising signal routing circuitry that couples one or more output ports of the multi-tone generator circuit to the one or more second input ports of the quantum control interconnect circuitry, wherein which one or more of the one or more output ports of the multi-tone generator circuit is connected to which one or more of the one or more second input ports of the quantum control interconnect circuitry is different for different configurations of the signal routing circuitry. 5. The system of claim 4 , wherein which of the different configurations of the signal routing circuitry is used is controllable via one or more digital control signals from the quantum control pulse generation circuitry. 6. The system of claim 3 , wherein the quantum control interconnect circuitry comprises: one or more third input ports for reception of quantum element readout pulses to be sent to one or more quantum element readout circuits; one or more fourth input ports for reception of a variable-frequency signal; a second mixer for upconversion of readout pulses received via the one or more second input ports using the variable-frequency signal; and one or more second output ports configured to convey upconverted readout pulses from the second mixer to the one or more quantum element readout circuits. 7. The system of claim 6 , wherein the quantum control interconnect circuitry comprises: a fifth input port for receiving return pulses from the one or more quantum element readout circuits; a third mixer configured to downconvert the return pulses using the variable-frequency signal received; and a third output configured to convey downconverted return pulses from the third mixer to the quantum control pulse generation circuitry. 8. The system of claim 1 , wherein the multi-tone generator circuit comprises a crystal oscillator, a first signal processing circuit, a plurality of phase locked loops, and a plurality of resonator circuits wherein: the crystal oscillator is configured to generate a first fixed-frequency intermediary signal; the first signal processing circuit is configured to process the first fixed-frequency intermediary signal to generate a plurality of fixed-frequency intermediary signals; a frequency of each of the plurality of fixed-frequency intermediary signals is an integer multiple of a frequency of the first fixed-frequency intermediary signal; each of the plurality of phase locked loops is configured to receive a respective one of the plurality of fixed-frequency intermediary signals and receive an output of a respective one of the plurality of resonator circuits; and each of the plurality of resonator circuits is configured to receive an output of a respective one of the plurality of phase locked loops. 9. The system of claim 8 , wherein one or more outputs of the plurality of resonator circuits are one or more of the plurality of fixed-frequency signals. 10. The system of claim 8 , wherein two or more outputs of the plurality of resonator circuits are mixed together to generate one or more of the plurality of fixed-frequency signals. 11. The system of claim 8 , wherein the processing of the first fixed-frequency intermediary signal by the first signal processing circuit does not use any voltage controlled oscillators. 12. The system of claim 8 , wherein the processing of the first fixed-frequency intermediary signal by the first signal processing circuit does not use any feedback loops. 13. The system of claim 8 , wherein the first signal processing circuit comprises one or more mixers, one or more amplifiers, one or more filters, one or more frequency multipliers and one or more splitters. 14. The system of claim 3 , wherein the multi-tone generator circuit comprises a crystal oscillator, a first signal processing circuit, a phase locked loop, a resonator circuit, and a second signal processing circuit wherein: the crystal oscillator is configured to generate a first fixed-frequency intermediary signal; the first signal processing circuit is configured to process the first fixed-frequency intermediary signal to generate a plurality of fixed-frequency intermediary signals; a frequency of each of the plurality of fixed-frequency intermediary signals is an integer multiple of a frequency of the first fixed-frequency intermediary signal; the phase locked loop is configured to receive one of the plurality of fixed-frequency intermediary signals and an output of the resonator circuit; the resonator circuit is configured to receive an output of the phase locked loop; and the second signal processing circuit is configured to mix an output of the resonator circuit and one or more of the plurality of fixed-frequency intermediary signals to generate one or more of the plurality of fixed-frequency signals. 15. The system of claim 14 , wherein a bandwidth of the phase locked loop is set such that phase noise of the plurality of fixed-frequency signals at offset frequencies below a first frequency is phase noise of the first signal processing circuit, and phase noise of the plurality of fixed-frequency signals at frequencies above a second frequency, higher than the first frequency, is phase noise of the resonator circuit. 16. The system of claim 14 , wherein the processing of the first fixed-frequency intermediary signal by the first signal processing circuit does not u