Measurement-induced Boolean dynamics and controllability for closed quantum networks
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Qi, Hongsheng
Mu, Biqiang
Petersen, Ian
Shi, Guodong
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Elsevier Ltd
Abstract
In this paper, we study dynamical quantum networks which evolve according to Schrödinger equations
but subject to sequential local or global quantum measurements. A network of qubits forms a composite quantum system whose state undergoes unitary evolution in between periodic measurements,
leading to hybrid quantum dynamics with random jumps at discrete time instances along a continuous
orbit. The measurements either act on the entire network of qubits, or only a subset of qubits.
First of all, we reveal that this type of hybrid quantum dynamics induces probabilistic Boolean
recursions representing the measurement outcomes. With global measurements, it is shown that such
resulting Boolean recursions define Markov chains whose state-transitions are fully determined by
the network Hamiltonian and the measurement observables. Particularly, we establish an explicit and
algebraic representation of the underlying recursive random mapping driving such induced Markov
chains. Next, with local measurements, the resulting probabilistic Boolean dynamics is shown to
be no longer Markovian. The state transition probability at any given time becomes dependent on
the entire history of the sample path, for which we establish a recursive way of computing such
non-Markovian probability transitions. Finally, we adopt the classical bilinear control model for the
continuous Schrödinger evolution, and show how the measurements affect the controllability of the
quantum networks.
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CC BY-NC-ND
http://creativecommons.org/licenses/by-nc-nd/4.0/
http://creativecommons.org/licenses/by-nc-nd/4.0/
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