We consider discrete-time quantum systems subject to Quantum Non-Demolition
(QND) measurements and controlled by an adjustable unitary evolution between
two successive QND measures. In open-loop, such QND measurements provide a
non-deterministic preparation tool exploiting the back-action of the
measurement on the quantum state. We propose here a systematic method based on
elementary graph theory and inversion of Laplacian matrices to construct strict
control-Lyapunov functions. This yields an appropriate feedback law that
stabilizes globally the system towards a chosen target state among the
open-loop stable ones, and that makes in closed-loop this preparation
deterministic. We illustrate such feedback laws through simulations
corresponding to an experimental setup with QND photon counting

Amini, Hadis

Mirrahimi, Mazyar

Rouchon, Pierre

English

arXiv

International audienceWe consider discrete-time quantum systems subject to Quantum Non-Demolition (QND) measurements and controlled by an adjustable unitary evolution between two successive QND measures. In open-loop, such QND measurements provide a non-deterministic preparation tool exploiting the back-action of the measurement on the quantum state. We propose here a systematic method based on elementary graph theory and inversion of Laplacian matrices to construct strict control-Lyapunov functions. This yields an appropriate feedback law that stabilizes globally the system towards a chosen target state among the open-loop stable ones, and that makes in closed-loop this preparation deterministic. We illustrate such feedback laws through simulations corresponding to an experimental setup with QND photon counting

HAL-MINES ParisTech

Design of strict control-Lyapunov functions for Quantum systems with QND measurements

Hal-Diderot

INRIA a CCSD electronic archive server

Abstract—We consider discrete-time quantum systems sub-ject to Quantum Non-Demolition (QND) measurements and controlled by an adjustable unitary evolution between two successive QND measures. In open-loop, such QND measure-ments provide a non-deterministic preparation tool exploiting the back-action of the measurement on the quantum state. We propose here a systematic method based on elementary graph theory and inversion of Laplacian matrices to construct strict control-Lyapunov functions. This yields an appropriate feedback law that stabilizes globally the system towards a chosen target state among the open-loop stable ones, and that makes in closed-loop this preparation deterministic. We illus-trate such feedback laws through simulations corresponding to an experimental setup with QND photon counting. I

H. Amini

P. Rouchon

M. Mirrahimi

CiteSeerX

Design of Strict Control-Lyapunov Functions for Quantum Systems with QND Measurements

Crossref

HAL: Hyper Article en Ligne

http://cas.ensmp.fr/~rouchon/publications/PR2011/CDC2011-Amini-a.pdf

Design of Strict Control-Lyapunov Functions for Quantum Systems with QND
  Measurements

Design of Strict Control-Lyapunov Functions for Quantum Systems with QND Measurements

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