Superconducting systems
Learn how Boulder Opal can be applied to superconducting systems
Design noise-robust single-qubit gates for IBM Qiskit
Increasing robustness against dephasing and control noise using Boulder Opal pulses
Design noise-robust single-qubit gates for Rigetti Quil-T
Increasing robustness against control noise using Boulder Opal pulses
Perform model-based robust optimization for the cross-resonance gate
Increasing robustness against crosstalk in a two-qubit entangling operation
Demonstrate SU(3) gates on superconducting hardware
Hamiltonian-agnostic rapid tune-up of an arbitrary unitary on a qutrit
Design fast optimal SNAP gates in superconducting resonators
Engineering fast, leakage-free gates in superconducting cavity-qubit systems
Perform optimal Fock state generation in superconducting resonators
Engineering fast cavity state generation in superconducting cavity-qubit systems
Design error-detectable entangling gates for superconducting resonators in dual-rail encoding
Robust $ZZ_\Theta$ gate with a transmon ancilla engineered using Boulder Opal
Design error-robust digital SFQ controls for superconducting qubits
Generating single flux quantum gates robust to leakage and frequency drift
Perform noise spectroscopy in superconducting hardware
Reconstructing noise power spectrum density in transmon qubits using dynamical decoupling sequences
