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Exploiting landscape geometry to enhance quantum optimal control

Martín Larocca, Esteban Calzetta, Diego A. Wisniacki

2020Physical review. A/Physical review, A30 citationsDOIOpen Access PDF

Abstract

The successful application of quantum optimal control (QOC) over the past decades has unlocked the possibility of directing the dynamics of quantum systems. Nevertheless, solutions obtained from QOC algorithms are usually highly irregular, making them unsuitable for direct experimental implementation. In this paper, we propose a method to reshape those unattractive optimal controls. The approach is based on the fact that solutions to QOC problems are not isolated policies but constitute multidimensional submanifolds of control space. This was originally shown for finite-dimensional systems. Here, we analytically prove that this property is still valid in a continuous variable system. The degenerate subspace can be effectively traversed by moving in the null subspace of the Hessian of the cost function, allowing for the pursuit of secondary objectives. To demonstrate the usefulness of this procedure, we apply the method to smooth and compress optimal protocols in order to meet laboratory demands.

Topics & Concepts

Hessian matrixSubspace topologyComputer scienceOptimal controlDegenerate energy levelsProperty (philosophy)QuantumFunction (biology)Mathematical optimizationSpace (punctuation)Control (management)Quantum systemApplied mathematicsMathematicsTopology (electrical circuits)Artificial intelligencePhysicsQuantum mechanicsEvolutionary biologyPhilosophyBiologyEpistemologyCombinatoricsOperating systemSpectroscopy and Quantum Chemical StudiesQuantum Information and CryptographyLaser-Matter Interactions and Applications
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