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This article is cited in 10 scientific papers (total in 10 papers)
Uncomputability and complexity of quantum control
Denys I. Bondara, Alexander N. Pechenbc a Tulane University, New Orleans, LA 70118, USA
b Steklov Mathematical Institute of Russian Academy of Sciences, Moscow 119991, Russia
c National University of Science and Technology "MISIS", Moscow 119049, Russia
Abstract:
In laboratory and numerical experiments, physical quantities are known with a fnite precision and
described by rational numbers. Based on this, we deduce that quantum control problems both for
open and closed systems are in general not algorithmically solvable, i.e., there is no algorithm that can
decide whether dynamics of an arbitrary quantum system can be manipulated by accessible external
interactions (coherent or dissipative) such that a chosen target reaches a desired value. This conclusion
holds even for the relaxed requirement of the target only approximately attaining the desired value.
These fndings do not preclude an algorithmic solvability for a particular class of quantum control
problems. Moreover, any quantum control problem can be made algorithmically solvable if the set of
accessible interactions (i.e., controls) is rich enough. To arrive at these results, we develop a technique
based on establishing the equivalence between quantum control problems and Diophantine equations,
which are polynomial equations with integer coefcients and integer unknowns. In addition to proving
uncomputability, this technique allows to construct quantum control problems belonging to diferent
complexity classes. In particular, an example of the control problem involving a two-mode coherent
feld is shown to be NP-hard, contradicting a widely held believe that two-body problems are easy.
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