Abstract
Data-driven methods for establishing quantum optimal control (QOC) using time-dependent control pulses tailored to specific quantum dynamical systems and desired control objectives are critical for many emerging quantum technologies. We develop a data-driven regression procedure, bilinear dynamic mode decomposition (biDMD), that leverages time-series measurements to establish quantum system identification for QOC. The biDMD optimization framework is a physics-informed regression that makes use of the known underlying Hamiltonian structure. Further, the biDMD can be modified to model both fast and slow sampling of control signals, the latter by way of stroboscopic sampling strategies. The biDMD method provides a flexible, interpretable, and adaptive regression framework for real-time, online implementation in quantum systems. Further, the method has strong theoretical connections to Koopman theory, which approximates nonlinear dynamics with linear operators. In comparison with many machine learning paradigms minimal data is needed to construct a biDMD model, and the model is easily updated as new data is collected. We demonstrate the efficacy and performance of the approach on a number of representative quantum systems, showing that it also matches experimental results.
Highlights
Quantum optimal control (QOC) is a comprehensive mathematical framework for quantum control in which time-dependent control pulses are tailored to specific quantum dynamical systems and desired experimental objectives [1]
We show how the Dynamic Mode Decomposition (DMD) system identification framework can be applied to the study of quantum control via a bilinear DMD algorithm [46, 47]
In cases where theoretical models are inaccurate or unknown, data-driven system identification is essential for practical quantum optimal control (QOC)
Summary
Quantum optimal control (QOC) is a comprehensive mathematical framework for quantum control in which time-dependent control pulses are tailored to specific quantum dynamical systems and desired experimental objectives [1]. In QOC, practical control design depends on an experimentally-accurate model of the governing quantum dynamics and the action of controls. In this manuscript, we introduce the data-driven regression framework known as dynamic mode. Koopman theory for classical system identification and control is one paradigm that even uses the operator-theoretic language developed for quantum dynamics [33,34,35]. In this context, natural interpretations of DMD using Floquet theory and treatments of biDMD from the perspective of average Hamiltonian theory are discussed with examples
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