Add to ORKGWithin the framework of the Accardi-Fagnola-Quaegebeur (AFQ) representation free calculus of \cite{b}, we consider the problem of controlling the size of a quantum stochastic flow generated by a unitary stochastic evolution affected by quantum noise. In the case when the evolution is driven by first order white noise (which includes quantum Brownian motion) the control is shown to be given in terms of the solution of an algebraic Riccati equation. This is done by first solving the problem of controlling (by minimizing an associated quadratic performance criterion) a stochastic process whose evolution is described by a stochastic differential equation of the type considerd in \cite{b}. The solution is given as a feedback control law in ter...
We prove the stochastic independence of the basic integrators of the renormalized square of white no...
A stochastic dynamical system is a system composed of many interacting components which includes sto...
We investigate the effect of stochastic control errors on the Hamiltonian that controls a closed qua...
Within the framework of the Accardi-Fagnola-Quaegebeur (AFQ) representation free calculus of \cite{b...
We consider the problem of controlling the size of an elementary quantum stochastic flow generated ...
Controlling the size of the solution of a (deterministic, stochastic or quantum stochastic) differen...
The problem of controlling quantum stochastic evolutions arises naturally in several di erent elds...
We review the basic features of the quantum stochastic calculus. Iteration schemes for the computat...
38 pages"Quantum trajectories" are solutions of stochastic differential equations of non-usual type....
We look at time evolution of a physical system from the point of view of dynamical control theory. N...
Abstract. The control process that minimizes the quadratic per-formance functional associated with a...
The quantum stochastic differenti,al equation satisfied by the unitary operator U(t) = e(iE)(l) with...
We prove the It\^{o} multiplication table for the stochastic differentials of the universal envelopi...
No quantum measurement can give full information on the state of a quantum system; hence any quantum...
We prove the stochastic independence of the basic integrators of the renormalized square of white no...
A stochastic dynamical system is a system composed of many interacting components which includes sto...
We investigate the effect of stochastic control errors on the Hamiltonian that controls a closed qua...
Within the framework of the Accardi-Fagnola-Quaegebeur (AFQ) representation free calculus of \cite{b...
We consider the problem of controlling the size of an elementary quantum stochastic flow generated ...
Controlling the size of the solution of a (deterministic, stochastic or quantum stochastic) differen...
The problem of controlling quantum stochastic evolutions arises naturally in several di erent elds...
We review the basic features of the quantum stochastic calculus. Iteration schemes for the computat...
38 pages"Quantum trajectories" are solutions of stochastic differential equations of non-usual type....
We look at time evolution of a physical system from the point of view of dynamical control theory. N...
Abstract. The control process that minimizes the quadratic per-formance functional associated with a...
The quantum stochastic differenti,al equation satisfied by the unitary operator U(t) = e(iE)(l) with...
We prove the It\^{o} multiplication table for the stochastic differentials of the universal envelopi...
No quantum measurement can give full information on the state of a quantum system; hence any quantum...
We prove the stochastic independence of the basic integrators of the renormalized square of white no...
A stochastic dynamical system is a system composed of many interacting components which includes sto...
We investigate the effect of stochastic control errors on the Hamiltonian that controls a closed qua...