Hessian-based optimization of quantum dynamics under constrained control
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Abstract
Efficient optimization of quantum systems with large state or control spaces is a necessity for reaching fault tolerant thresholds. A standard tool for optimizing simulated quantum dynamics is the gradient-based \textsc{grape} algorithm, which has been successfully applied in a wide range of different branches of quantum physics. In this work, we derive and implement exact $2^{\mathrm{nd}}$ order analytical Hessian of the coherent dynamics and find improvements compared to the approximate $2^{\mathrm{nd}}$ order \textsc{bfgs} standard optimization. We demonstrate performance improvements for both the best and average errors of constrained unitary gate synthesis on a circuit-\textsc{qed} system over a broad range of different gate durations.