We study the relationship between the classical Hamilton flow and the quantum Schrödinger evolution where the Hamiltonian is a degree-2 complex-valued polynomial. When the flow obeys a strict positivity condition equivalent to compactness of the evolution operator, we find geometric expressions for the L^2 operator norm and a singular-value decomposition of the Schrödinger evolution, using the Hamilton flow. The flow also gives a geometric composition law for these operators, which correspond to a large class of integral operators with nondegenerate Gaussian kernels
We present a new setting of the geometric Hamilton-Jacobi theory by using the so-called time-evoluti...
In classical mechanics we divide Hamiltonian systems into integrable and nonintegrable systems. This...
AbstractThe operatorial calculus of Feinsilver is extended to a class of Hamiltonians possessing ter...
We study the relationship between the classical Hamilton flow and the quantum Schrödinger evolution ...
We consider the Hamiltonian operator associated to the quantum stochastic differential equation intr...
We prove that the decay of the eigenfunctions of harmonic oscillators, uniform electric or magnetic ...
We consider the quantum stochastic differential equation introduced by Hudson and Parthasarathy to d...
We prove that the decay of the eigenfunctions of harmonic oscillators, uniform electric or magnetic ...
The semi-classical dynamics of a pseudo-differential operator on a manifold is the quantum analogous...
AbstractThe Weyl correspondence that associates a quantum-mechanical operator to a Hamiltonian funct...
In this paper we analyze the evolution of the time averaged energy densities associatedwith a family...
In this paper we analyze the evolution of the time averaged energy densities associated with a famil...
We construct a family of global Fourier Integral Operators, defined for arbitrary large times, repre...
We study a non-autonomous, non-linear evolution equation on the space of operators on a complex Hilb...
AbstractTwo of the oldest known classical integrable systems are: (i) n-decoupled harmonic oscillato...
We present a new setting of the geometric Hamilton-Jacobi theory by using the so-called time-evoluti...
In classical mechanics we divide Hamiltonian systems into integrable and nonintegrable systems. This...
AbstractThe operatorial calculus of Feinsilver is extended to a class of Hamiltonians possessing ter...
We study the relationship between the classical Hamilton flow and the quantum Schrödinger evolution ...
We consider the Hamiltonian operator associated to the quantum stochastic differential equation intr...
We prove that the decay of the eigenfunctions of harmonic oscillators, uniform electric or magnetic ...
We consider the quantum stochastic differential equation introduced by Hudson and Parthasarathy to d...
We prove that the decay of the eigenfunctions of harmonic oscillators, uniform electric or magnetic ...
The semi-classical dynamics of a pseudo-differential operator on a manifold is the quantum analogous...
AbstractThe Weyl correspondence that associates a quantum-mechanical operator to a Hamiltonian funct...
In this paper we analyze the evolution of the time averaged energy densities associatedwith a family...
In this paper we analyze the evolution of the time averaged energy densities associated with a famil...
We construct a family of global Fourier Integral Operators, defined for arbitrary large times, repre...
We study a non-autonomous, non-linear evolution equation on the space of operators on a complex Hilb...
AbstractTwo of the oldest known classical integrable systems are: (i) n-decoupled harmonic oscillato...
We present a new setting of the geometric Hamilton-Jacobi theory by using the so-called time-evoluti...
In classical mechanics we divide Hamiltonian systems into integrable and nonintegrable systems. This...
AbstractThe operatorial calculus of Feinsilver is extended to a class of Hamiltonians possessing ter...
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