Propagation of Quantum Expectations with Husimi Functions

Keller, Johannes; Lasser, Caroline

doi:10.1137/120889186

Cited by 13 publications

(18 citation statements)

References 11 publications

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“…There is no analogue in the case of non-linear flows (see de Gosson [34]). However, we conjecture that it is possible to obtain asymptotic equalities in the limit → 0 (with arbitrary accuracy) using the method developed by Lasser and her coworkers [22,56], and which yield a refinement of Egorov's theorem [15] on transformation properties of pseudo-differential operators.…”

mentioning

confidence: 99%

Paths of canonical transformations and their quantization

Gosson

2015

Rev. Math. Phys.

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In their simplest formulations, classical dynamics is the study of Hamiltonian flows and quantum mechanics of propagators. Both are linked, and emerge from the datum of a single classical concept, the Hamiltonian function. We study and emphasize the analogies between Hamiltonian flows and quantum propagators; this allows us to verify G. Mackey's observation that quantum mechanics (in its Weyl formulation) is a refinement of Hamiltonian mechanics. We discuss in detail the metaplectic representation, which very explicitly shows the close relationship between classical mechanics and quantum mechanics; the latter emerging from the first by lifting Hamiltonian flows to the double covering of the symplectic group. We also give explicit formulas for the factorization of Hamiltonian flows into simpler flows, and prove a quantum counterpart of these results.

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confidence: 99%

Paths of canonical transformations and their quantization

Gosson

2015

Rev. Math. Phys.

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“…Discretization. For the algorithmic discretization of Corollary 4.1 we proceed similarly as in [16,10,14]. We consider various smooth functions a : R 2d → R and evaluate the phase space integral on the right hand side of the semiclassical approximation…”

Section: Numerical Experimentsmentioning

confidence: 99%

“…As the initial state we consider the Gaussian wave packet ψ 0 = g z with phase space center z = (1, 0, 0, 0). This setup has already been considered in [5,16,14,10]. We investigate the dynamics of the following symbols a : R 4 → R, (1) Position: a(q, p) = q 1 and a(q, p) = q 2 , (2) Momentum: a(q, p) = p 1 and a(q, p) = p 2 , (3) Kinetic and potential energy: a(q, p) = 1 2 |p| 2 and a(q, p) = V (q), (4) Total energy: a(q, p) = 1 2 |p| 2 + V (q), and compare the outcome of the new algorithm with the naive, first-order Husimi approximation…”

Section: Numerical Experimentsmentioning

confidence: 99%

“…One-dimensional cubic well. For the spectrogram algorithm we employed 2 14 Halton points and the eighth-order integrator with time stepping 10 −2 , which results in a computational time of 2 seconds. The quantum references are generated by means of a Strang splitting with 2 15 Fourier modes on the interval [−40, 4].…”

Section: 4mentioning

confidence: 99%

“…Replacing the new density by the Husimi function in Corollary 4.1 deteriorates the approximation in the sense thate −iHt/ε ψ, op(a)e −iHt/ε ψ = R 2d (a • Φ t )(z)H ψ (z)dz + O(ε)as ε → 0. It requires an additional system of coupled ODEs involving higher order derivatives of the Hamilton function h to retain second order accuracy with respect to ε; see[14, Theorem 3].…”

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confidence: 99%

See 2 more Smart Citations

A New Phase Space Density for Quantum Expectations

Keller

Lasser

Ohsawa³

2016

SIAM J. Math. Anal.

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Abstract. We introduce a new density for the representation of quantum states on phase space. It is constructed as a weighted difference of two smooth probability densities using the Husimi function and first-order Hermite spectrograms. In contrast to the Wigner function, it is accessible by sampling strategies for positive densities. In the semiclassical regime, the new density allows to approximate expectation values to second order with respect to the high frequency parameter and is thus more accurate than the uncorrected Husimi function. As an application, we combine the new phase space density with Egorov's theorem for the numerical simulation of time-evolved quantum expectations by an ensemble of classical trajectories. We present supporting numerical experiments in different settings and dimensions.

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Polyanalytic Toeplitz Operators: Isomorphisms, Symbolic Calculus and Approximation of Weyl Operators

Keller¹,

Luef²

2021

J Fourier Anal Appl

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We discuss an extension of Toeplitz quantization based on polyanalytic functions. We derive isomorphism theorem for polyanalytic Toeplitz operators between weighted Sobolev-Fock spaces of polyanalytic functions, which are images of modulation spaces under polyanalytic Bargmann transforms. This generalizes well-known results from the analytic setting. Finally, we derive an asymptotic symbol calculus and present an asymptotic expansion of complex Weyl operators in terms of polyanalytic Toeplitz operators.

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Propagation of Quantum Expectations with Husimi Functions

Cited by 13 publications

References 11 publications

Paths of canonical transformations and their quantization

Paths of canonical transformations and their quantization

A New Phase Space Density for Quantum Expectations

Polyanalytic Toeplitz Operators: Isomorphisms, Symbolic Calculus and Approximation of Weyl Operators

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