Litcius/Paper detail

Analytic Filter-Function Derivatives for Quantum Optimal Control

Isabel Nha Minh Le, Julian D. Teske, Tobias Hangleiter, Pascal Cerfontaine, Hendrik Bluhm

2022Physical Review Applied17 citationsDOIOpen Access PDF

Abstract

Autocorrelated noise appears in many solid-state qubit systems and hence needs to be taken into account when developing gate operations for quantum information processing. However, explicitly simulating this kind of noise is often less efficient than approximate methods. Here, we focus on the filter function formalism, which allows the computation of gate fidelities in the presence of autocorrelated classical noise. Hence, this formalism can be combined with optimal control algorithms to design control pulses, which optimally implement quantum gates. To enable the use of gradient-based algorithms with fast convergence, we present analytically derived filter function gradients with respect to control pulse amplitudes, and analyze the computational complexity of our results. When comparing pulse optimization using our derivatives to a gradient-free approach, we find that the gradient-based method is roughly 2 orders of magnitude faster for our test cases. We also provide a modular computational implementation compatible with quantum optimal control packages.

Topics & Concepts

AutocorrelationComputer scienceQuantum computerOptimal controlFilter (signal processing)ComputationModular designAlgorithmFormalism (music)QuantumMathematicsMathematical optimizationQuantum mechanicsPhysicsOperating systemVisual artsArtStatisticsComputer visionMusicalQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum and electron transport phenomena