Quantum optimal control via gradient ascent in function space and the time-bandwidth quantum speed limit

A gradient ascent method for optimal quantum control synthesis is presented that employs a gradient derived with respect to the coefficients of a functional basis expansion of the control. Restricting the space of allowable controls to weighted sums of the Slepian sequences efficiently parameterizes...

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Veröffentlicht in:	arXiv.org 2018-04
1. Verfasser:	Lucarelli, Dennis
Format:	Artikel
Sprache:	eng
Schlagworte:	Ascent Bandwidths Function space Optimal control Physics - Quantum Physics Pulse duration Qubits (quantum computing) Thermal expansion
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description	A gradient ascent method for optimal quantum control synthesis is presented that employs a gradient derived with respect to the coefficients of a functional basis expansion of the control. Restricting the space of allowable controls to weighted sums of the Slepian sequences efficiently parameterizes the control in terms of bandwidth, resolution and pulse duration. A bound showing minimum time evolutions scaling with the inverse of the control bandwidth [S. Lloyd and S. Montangero, PRL, 113, 010502, (2014)] is recovered and the method is shown numerically to achieve the bound on entangling two-qubit quantum gates.
doi_str_mv	10.48550/arxiv.1611.00188
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subjects	Ascent Bandwidths Function space Optimal control Physics - Quantum Physics Pulse duration Qubits (quantum computing) Thermal expansion
title	Quantum optimal control via gradient ascent in function space and the time-bandwidth quantum speed limit
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