Contribuições de trajetórias complexas ao propagador semiclássico para estados coerentes / Contributions of complex trajectories to semiclassical propagator for coherent states

Barreto, Wendell Pereira, 1987-

01 July 2014

Orientador: Marcus Aloizio Martinez de Aguiar / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-24T22:36:15Z (GMT). No. of bitstreams: 1 Barreto_WendellPereira_M.pdf: 1811207 bytes, checksum: 0f8c73a79029cd1792710999b0f258a0 (MD5) Previous issue date: 2014 / Resumo: A evolução temporal de estados quânticos é estudada do ponto de vista semiclássico usando o propagador na representação de estados coerentes. No limite semiclássico o propagador pode ser calculado em termos de soluções complexas das equações de Hamilton que devem satisfazer condições de contorno apropriadas. No entanto, nem todas as soluções podem ser utilizadas no cálculo do propagador. Certas trajetórias, denominadas não contribuintes devem ser descartadas, pois dão contribuições incorretas ao propagador. Aqui, exploramos a questão das trajetórias não contribuintes, que é um dos problemas mais sérios na aplicação sistemática das expressões semiclássicas envolvendo órbitas complexas. Para isso consideramos uma classe de problemas unidimensionais não-lineares onde as soluções clássicas e quânticas poder ser obtidas analiticamente. Dessa forma, o propagador semiclássico pode ser escrito de forma explícita, o que permite uma análise detalhada da contribuição de cada trajetória. Definimos então um critério mais preciso para a exclusão de soluções espúrias e, enfim, melhorar o cálculo semiclássico. O sistema foco neste estudo foi o oscilador harmônico ao quadrado, cuja dinâmica tem solução analítica e está presente em problemas de óptica não linear / Abstract: The time evolution of quantum states is studied in the semiclassical limit using the semiclassical propagator in the coherent-state representation. In the semiclassical limit the quantum propagator can be calculated with complex solutions of Hamilton's equations satisfying appropriate boundary conditions. However, not all these solutions can be used in the expression for the propagator. Some trajectories, called non contributing trajectories, give incorrect contributions to the propagator and should be excluded. In this work the issue of non-contributing trajectories, which is one of the most serious problems in the systematic application of semiclassical expression involving complex orbits, is studied. We explore a class of nonlinear one-dimensional problems for which classical and quantum solutions can be analytically obtained. For these problems, the semiclassical propagator can be written explicitty allowing a detailed analisys of the contribution of each trajectory. In this work we will focus on the ''squared harmonic oscillator'', it can be solved analytically and it is present in problems of nonlinear optics / Mestrado / Física / Mestre em Física

Trajetórias complexas

Propagador

Limite semiclássico

Complex trajectories

Propagator

Semiclassical limit

Effet tunnel dans les systèmes complexes. / Tunnelling in complex systems

Le Deunff, Jérémy

18 May 2011

Les travaux présentés dans cette thèse s’inscrivent dans le cadre général de la description de l’effet tunnel dans la limite semi classique h → 0. Nous présentons une nouvelle méthode de calcul direct de la largeur des doublets tunnel. L’expression obtenue est basée sur l’utilisation de traces d’opérateurs quantiques, dont l’opérateur d’évolution Û (T)prolongé analytiquement à l’aide d’un temps complexe T. L’étape suivante consiste en un développement semi classique de ces traces. Nous nous plaçons dans le cadre des systèmes intégrables unidimensionnels afin d’insister sur l’importance d’un temps complexe et on montre que le choix d’un chemin du temps [t] adapté, lors du calcul semi classique des traces, fournit un critère de sélection efficace des trajectoires complexes dominantes. Nous verrons que cette approche retrouve la technique des instantons dans la limite d’un temps purement imaginaire et qu’elle permet d’inclure les descriptions, inaccessibles par une rotation de Wick complète, de l’effet tunnel dynamique et résonant. Nous montrons également comment adapter cette méthode au taux de transmission tunnel d’un état localisé dans un minimum local vers un continuum d’états. Enfin, nous proposerons, en guise de perspectives,d’étudier l’effet tunnel résonant à partir de modèles intégrables présentant des îlots stables entourés de chaînes de tores pour lesquels nous tenterons d’adapter la théorie de l’effet tunnel assisté par les résonances. / The present work is developed within the general framework of the description of the tunneling effect in the semiclassical limit h → 0. We introduce a new method for the direct computation of the tunneling splittings. We get a trace formula involving the evolution operator continued in the complex plane using a complex time T. The next step is to obtain semi classical expansion of these traces. Within the framework of one dimensionnalintegrable systems, we show the key role of a complex time. When performing semiclassical calculations, an appropriate complex-time paths provide an efficient criterion in order toselect the dominant complex trajectories involved in the traces. We will show that our approach includes instanton techniques in the limit of a purely imaginary time and describes dynamical tunneling and resonant tunneling for which a complete Wick is not sufficient.We will show also how our method works for the decay rates. Finally, as a perspective,we will study resonant tunneling from integrable models which exhibit prominent islands surrounded by chains of tori. From these models, we will try to apply the theory of resonant assisted tunneling to integrable systems.

Rotation de Wick

Temps complexe

Trajectoire complexe

Dynamical tunneling

Resonant tunneling

Instantons

WICK rotation

Semiclassical methods

Complex time

Complex trajectories

Geometric approach to multi-scale 3D gesture comparison

Ochoa Mayorga, Victor Manuel

11 1900

The present dissertation develops an invariant framework for 3D gesture comparison studies. 3D gesture comparison without Lagrangian models is challenging not only because of the lack of prediction provided by physics, but also because of a dual geometry representation, spatial dimensionality and non-linearity associated to 3D-kinematics. In 3D spaces, it is difficult to compare curves without an alignment operator since it is likely that discrete curves are not synchronized and do not share a common point in space. One has to assume that each and every single trajectory in the space is unique. The common answer is to assert the similitude between two or more trajectories as estimating an average distance error from the aligned curves, provided that the alignment operator is found. In order to avoid the alignment problem, the method uses differential geometry for position and orientation curves. Differential geometry not only reduces the spatial dimensionality but also achieves view invariance. However, the nonlinear signatures may be unbounded or singular. Yet, it is shown that pattern recognition between intrinsic signatures using correlations is robust for position and orientation alike. A new mapping for orientation sequences is introduced in order to treat quaternion and Euclidean intrinsic signatures alike. The new mapping projects a 4D-hyper-sphere for orientations onto a 3D-Euclidean volume. The projection uses the quaternion invariant distance to map rotation sequences into 3D-Euclidean curves. However, quaternion spaces are sectional discrete spaces. The significance is that continuous rotation functions can be only approximated for small angles. Rotation sequences with large angle variations can only be interpolated in discrete sections. The current dissertation introduces two multi-scale approaches that improve numerical stability and bound the signal energy content of the intrinsic signatures. The first is a multilevel least squares curve fitting method similar to Haar wavelet. The second is a geodesic distance anisotropic kernel filter. The methodology testing is carried out on 3D-gestures for obstetrics training. The study quantitatively assess the process of skill acquisition and transfer of manipulating obstetric forceps gestures. The results show that the multi-scale correlations with intrinsic signatures track and evaluate gesture differences between experts and trainees.

3D gesture comparison

Multiscale curvature

Curvature-torsion

differential geometry

complex trajectories

quaternion trajectories

quaternion projections

quaternion metrics

3D trajectory smoothing

curvature signature correlations

qualitative skill transfer measure

medical manipulative gestures

nonlinear signatures

anisotropic kernel filter

curvature numerical stability

quaternion smoothing

kinematics

motor skill transfer

curvature signature

torsion signature

arc-length parameterization

tensors

Frenet-Serret quaternion framework

nonlinear kernel filter

geodesic distance

finite difference methods

differential convolution filter

Savitzky-Golay filter

least squares curve fitting

curvature neighborhood

multilevel curvature analysis

medical training

child bearing simulator

robotic simulator

motion tracking

3D electromagnetic trackers

sequence comparison

medical training

Geometric approach to multi-scale 3D gesture comparison

Ochoa Mayorga, Victor Manuel

Unknown Date

No description available.

3D gesture comparison

Multiscale curvature

Curvature-torsion

differential geometry

complex trajectories

quaternion trajectories

quaternion projections

quaternion metrics

3D trajectory smoothing

curvature signature correlations

qualitative skill transfer measure

medical manipulative gestures

nonlinear signatures

anisotropic kernel filter

curvature numerical stability

quaternion smoothing

kinematics

motor skill transfer

curvature signature

torsion signature

arc-length parameterization

tensors

Frenet-Serret quaternion framework

nonlinear kernel filter

geodesic distance

finite difference methods

differential convolution filter

Savitzky-Golay filter

least squares curve fitting

curvature neighborhood

multilevel curvature analysis

medical training

child bearing simulator

robotic simulator

motion tracking

3D electromagnetic trackers

sequence comparison

medical training