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From Pulses to Circuits and Back Again: A Quantum Optimal Control Perspective on Variational Quantum Algorithms

Alicia B. Magann, Christian Arenz, Matthew D. Grace, Tak-San Ho, Robert L. Kosut, Jarrod R. McClean, Herschel A. Rabitz, Mohan Sarovar

2021PRX Quantum102 citationsDOIOpen Access PDF

Abstract

The last decade has witnessed remarkable progress in the development of quantum technologies. Although fault-tolerant devices likely remain years away, the noisy intermediate-scale quantum devices of today may be leveraged for other purposes. Leading candidates are variational quantum algorithms (VQAs), which have been developed for applications including chemistry, optimization, and machine learning, but whose implementations on quantum devices have yet to demonstrate improvements over classical capabilities. In this Perspective, we propose a variety of ways that the performance of VQAs could be informed by quantum optimal control theory. A major theme throughout is the need for sufficient control resources in VQA implementations; we discuss different ways this need can manifest, outline a variety of open questions, and look to the future.

Topics & Concepts

Variety (cybernetics)QuantumPerspective (graphical)Computer scienceOptimal controlQuantum algorithmQuantum computerImplementationControl (management)Quantum circuitQuantum informationAlgorithmQuantum controlKey (lock)Quantum stateTheoretical computer scienceElectronic circuitQuantum technologyOpen quantum systemTheme (computing)Quantum systemQuantum networkTopology (electrical circuits)Quantum phase estimation algorithmQuantum gateMathematicsQuantum nanoscienceComputer engineeringQuantum operationQuantum information scienceScheme (mathematics)Quantum Computing Algorithms and ArchitectureQuantum Information and CryptographySpectroscopy and Quantum Chemical Studies
From Pulses to Circuits and Back Again: A Quantum Optimal Control Perspective on Variational Quantum Algorithms | Litcius