Recasts LEO quantum control in nonperturbative Floquet-Magnus framework to derive low-frequency pulse conditions, proves equivalence to prior zero-order results, and validates on spin-chain state transfer and two-level adiabatic speedup.
Li, Floquet-informed learning of periodically driven hamiltonians, arXiv preprint arXiv:2509.02331 (2025)
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Nonperturbative Leakage Elimination Operator-Based Quantum Control Pulse Design Beyond the High Frequency Driving Regime
Recasts LEO quantum control in nonperturbative Floquet-Magnus framework to derive low-frequency pulse conditions, proves equivalence to prior zero-order results, and validates on spin-chain state transfer and two-level adiabatic speedup.