High-Fidelity Software-Defined Quantum Logic on a Superconducting Qudit
Xian Wu, Spencer Tomarken, N. Anders Petersson, Luis A. Martinez, Yaniv Rosen, Jonathan L. DuBois
Abstract
We present an efficient approach to achieving arbitrary, high-fidelity control of a multilevel quantum system using optimal control techniques. As an demonstration, we implement a continuous, software-defined microwave pulse to realize a 0↔2 SWAP gate that achieves an average gate fidelity of 99.4%. We describe our procedure for extracting the system Hamiltonian, calibrating the quantum and classical hardware chain, and evaluating the gate fidelity. Our work represents an alternative, fully generalizable route towards achieving universal quantum control by leveraging optimal control techniques.
Topics & Concepts
FidelityQuantum logicComputer scienceSoftwareQuantum gateQuantumQuantum computerHigh fidelityPhysicsHamiltonian (control theory)Swap (finance)Topology (electrical circuits)Quantum mechanicsElectrical engineeringMathematicsMathematical optimizationProgramming languageEconomicsFinanceAcousticsEngineeringTelecommunicationsQuantum Information and CryptographyQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomena