Minimal Time Robust Two Qubit Gates in Circuit QED

  1. Joseph L. Allen,
  2. Robert Kosut,
  3. and Eran Ginossar
Fault tolerant quantum computing requires quantum gates with high fidelity. Incoherent errors reduce the fidelities of quantum gates when the operation time is too long. Optimal control
techniques can be used to decrease the operation time in theory, but generally do not take into account the realistic nature of uncertainty regarding the system parameters. We apply robust optimal control techniques to demonstrate that it is feasible to reduce the operation time of the cross-resonance gate in superconducting systems to under 100\,ns with two-qubit gate fidelities of F>0.99, where the gate fidelity will not be coherence limited. This is while ensuring robustness for up to 10\% uncertainty in the system, and having chosen a parameterization that aides in experimental feasibility. We find that the highest fidelity gates can be achieved in the shortest time for the transmon qubits compared with a two-level flux qubit system. This suggests that the third-level of the transmon may be useful for achieving shorter cross-resonance gate times with high fidelity. The results further indicate a speed limit for experimentally feasible pulses with the inclusion of robustness and the maximum amount of uncertainty allowable to achieve fidelities with F>0.999.

Optimal control of two qubits via a single cavity drive in circuit quantum electrodynamics

  1. Joseph L. Allen,
  2. Robert Kosut,
  3. Jaewoo Joo,
  4. Peter Leek,
  5. and Eran Ginossar
Optimization of the fidelity of control operations is of critical importance in the pursuit of fault tolerant quantum computation. We apply optimal control techniques to demonstrate
that a single drive via the cavity in circuit quantum electrodynamics can implement a high fidelity two-qubit all-microwave gate that directly entangles the qubits via the mutual qubit-cavity couplings. This is performed by driving at one of the qubits‘ frequencies which generates a conditional two-qubit gate, but will also generate other spurious interactions. These optimal control techniques are used to find pulse shapes that can perform this two-qubit gate with high fidelity, robust against errors in the system parameters. The simulations were all performed using experimentally relevant parameters and constraints.