AbstractIn this article we show that quantum dynamics is the most natural generalization of classical dynamics from the point of view of optimal control. Employing the techniques of dynamic programming, we derive the Schrödinger equation starting from the Lagrangian defined in terms of Nelson's forward and backward velocities. The generalization to the relativistic case is also analyzed and the Klein Gordon Equation is similarly derived
Based on the Bohr's correspondence principle it is shown that relativistic mechanics and quantum mec...
[EN] This paper is an attempt to translate the quantum formulation from physics to general systems ...
The classical action: Integral (0,T) dt1 L(v(t1), x(t1),t1) may be varied to find a stationary solu...
This brief paper continues a development in earlier publications by Rosenbrock, in which results in ...
This thesis focuses on the optimal control of a class of closed 1 quantum systems. It encompasses an...
Abstract. Adiabatic quantum computation employs a slow change of a time-dependent control function (...
International audienceThe action functional can be used to define classical, quantum, closed, and op...
International audienceThe action functional can be used to define classical, quantum, closed, and op...
The purpose of this paper is to describe the application of the notion of viscosity solutions to sol...
Quantum systems are dynamic systems restricted by the principles of quantum mechanics (linearity of ...
We present a trajectory-based method that incorporates quantum effects in the context of Hamiltonian...
Similarity of equations of motion for the classical and quantum trajectories is used to introduce af...
We present a trajectory-based method that incorporates quantum effects in the context of Hamiltonian...
Several theoretical methods for the computation of quantum dynamical quantities are formulated, impl...
The Classical Newton-Lagrange equations of motion represent the fundamental physical law of mechanic...
Based on the Bohr's correspondence principle it is shown that relativistic mechanics and quantum mec...
[EN] This paper is an attempt to translate the quantum formulation from physics to general systems ...
The classical action: Integral (0,T) dt1 L(v(t1), x(t1),t1) may be varied to find a stationary solu...
This brief paper continues a development in earlier publications by Rosenbrock, in which results in ...
This thesis focuses on the optimal control of a class of closed 1 quantum systems. It encompasses an...
Abstract. Adiabatic quantum computation employs a slow change of a time-dependent control function (...
International audienceThe action functional can be used to define classical, quantum, closed, and op...
International audienceThe action functional can be used to define classical, quantum, closed, and op...
The purpose of this paper is to describe the application of the notion of viscosity solutions to sol...
Quantum systems are dynamic systems restricted by the principles of quantum mechanics (linearity of ...
We present a trajectory-based method that incorporates quantum effects in the context of Hamiltonian...
Similarity of equations of motion for the classical and quantum trajectories is used to introduce af...
We present a trajectory-based method that incorporates quantum effects in the context of Hamiltonian...
Several theoretical methods for the computation of quantum dynamical quantities are formulated, impl...
The Classical Newton-Lagrange equations of motion represent the fundamental physical law of mechanic...
Based on the Bohr's correspondence principle it is shown that relativistic mechanics and quantum mec...
[EN] This paper is an attempt to translate the quantum formulation from physics to general systems ...
The classical action: Integral (0,T) dt1 L(v(t1), x(t1),t1) may be varied to find a stationary solu...
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