Study on non-equilibrium quasi-stationary states for Hamiltonian systems with long-range interaction / 長距離相互作用を有するハミルトン系の非平衡準定常状態に関する研究

Ogawa, Shun

24 September 2013

京都大学 / 0048 / 新制・課程博士 / 博士(情報学) / 甲第17924号 / 情博第506号 / 新制||情||89(附属図書館) / 30744 / 京都大学大学院情報学研究科数理工学専攻 / (主査)教授 梅野 健, 教授 中村 佳正, 教授 船越 満明 / 学位規則第4条第1項該当 / Doctor of Informatics / Kyoto University / DFAM

statistical physics

quasi-stationary state

Vlasov equation

long-range interaction

Hamiltonian mean-field model

007

Universality of Kolmogorov's Cascade Picture in Inverse Energy Cascade Range of Two-dimensional turbulence / 2次元乱流のエネルギー逆カスケード領域における、コルモゴロフのカスケード描像の普遍性について

Mizuta, Atsushi

23 May 2014

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18446号 / 理博第4006号 / 新制||理||1578(附属図書館) / 31324 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)准教授 藤 定義, 教授 佐々 真一, 教授 早川 尚男 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

K41

KLB theory

two-dimensional turbulence

direct numerical simulation

inverse energy cascade

statistically stationary state

coherent vortices

400

Étude de processus en temps continu modélisant l'écoulement de flux de trafic routier / A study of continuous-time processes modelling traffic flow

Tordeux, Antoine

28 June 2010

Ce travail présente des modèles d'écoulement en temps continu de flux de trafic routier. En premier lieu, il s'agit de modèles microscopiques de poursuite. Un modèle par systèmes d'équations différentielles couplées est proposé, basé sur le temps inter-véhiculaire. Ce modèle intègre un temps de réaction et des possibilités d'anticipation pour chaque véhicule. Les paramètres sont estimés par maximum de vraisemblance dans un modèle statistique à deux niveaux. Des simulations permettent de caractériser le comportement d'une file de véhicules. Dans une approche stochastique, un modèle d'évolution de la distance inter-véhiculaire est étudié à l'aide du processus Markovien de saut zero-range. L'introduction d'un temps de réaction tend à produire des ondes cinématiques. D'autre part, un modèle d'écoulement de trafic par le processus Markovien de saut des misanthropes est proposé. Il s'agit d'une modélisation au niveau mésoscopique, adaptée à la simulation de flux de trafic sur un réseau / This work presents different continuous-time traffic flow models. Microscopic models are considered first. A model by coupled differential equation system is proposed, based on the time gap. It incorporates a reaction time parameter and some anticipation possibilities, for each vehicle. The parameters are estimated by maximum likelihood over a two-level statistical model. Simulations allow to characterise the behaviour of a vehicles line. In a stochastic approach, a model of the distance gap evolution is studied with a zero-range process. The introduction of a reaction time parameter produces kinematics waves. On the other hand, traffic flow model by a misanthropes process is proposed. It is a mesoscopic approach, adapted to the simulation of traffic flow on a network

Trafic routier

Ecoulement

Modèles de poursuite

Processus Markovien de saut

Régime stationnaire

Traffic flow

Car-following model

Nonlinear delay differential system

Markov jump process

Stationary state

Ordenamento e destilação em um modelo estocástico de partículas interagentes sob contrafluxo

Stock, Eduardo Velasco

January 2016

Neste trabalho estudamos uma dinâmica estocástica de partículas de duas espécies baseada em células. Basicamente, incorporamos algumas inovações em um modelo unidimensional proposto e resolvido por R. da Silva et al. (Physica A, 2015), que considera que em um célula, na ausência de partículas da espécie contrária, a partícula vai pra frente com uma probabilidade p, que representaria um campo na direção longitudinal de um corredor e fica na própria célula com q=1-p. Contudo, essa probabilidade p é reduzida de acordo com a concentração de partículas contrárias. Nosso trabalho não apenas estendeu o problema pra duas dimensões como também incluiu aspectos relativos a colisão e o espalhamento para células vizinhas. Nossos resultados são divididos em duas situações: a) Espécie contrária permanece imóvel funcionando como obstáculos b) Espécie contrária em movimento. Na primeira situação podemos ver uma interessante transição na distribuição dos tempos de travessia em função das concentrações dos obstáculos, por monitorar a curtose da distribuição. Quando a espécie contrária se movimenta, vemos que o tempo de destilação entre as partículas (tempo para que as espécies estejam geograficamente separadas no corredor) depende do parâmetro ligado ao espalhamento transversal das partículas, parâmetro este, que não influencia no caso das partículas paradas. Finalmente nós colocamos as partículas em um sistema com condições periódicas de contorno. Neste caso, podemos observar o aparecimento de padrões de bandas longitudinais ao campo, exatamente como ocorrem em problemas de coloides carregados sob a ação de campos longitudinais e em modelos de pedestres em corredores. Mostramos como o sistema relaxa para tal tipo de estado estacionário utilizando um adequado parâmetro de ordem ligado a segregação das partículas. Nosso modelo, diferentemente dos modelos para pedestres, não se baseia em equações tipo Langevin. Nossa abordagem é totalmente estocástica e por esse ponto de vista ainda mais fundamental e geral, podendo ser estendida para mais modelos de partículas em fluxos contrários. Nossa solução vem tanto através de simulações Monte Carlo bem como soluções das equações diferenciais parciais que descrevem o sistema e que são oriundas das recorrências estabelecidas para os caminhantes aleatórios. As simulações Monte Carlo e soluções via EDP mostram boa concordância em todos os aspectos analisados, tanto qualitativa quanto quantitativamente. / In this work we study a stochastic dynamic of particles of two types based on cells. Basically we incorporate some innovations on a one-dimensional model proposed and solved by R. da Silva et al. (Physica A, 2015) which considers that in the absence of particles of the opposite species in the cell a particle goes toward the next cell with probability p and returns to the previous cell with probability q = 1 p. However this motion probability linearly decreases with the relative density of the contrary species. Our work not only expands the problem for two dimensions but also includes collision aspects by adding scattering to the neighbouring cells. Our results are divided into two di erent categories: a) One of the species remain xed in their places which means that such particles will work as obstacles; b) Both species can move in the environment. In the rst situation we can observe, by monitoring the kurtosis, that an interesting transition of the crossing time distribution arises as the concentration of the obstacles increases. When both species can move we can observe that the distillation time (spent time for the complete geographical separation of the species in the corridor) depends on the parameter related to the perpendicular scattering of the particles. This same parameter has shown no in uence over the time distributions in the rst situation. Finally we implement periodic boundary conditions in the eld's direction. In this case we are able to observe the arising of band patterns parallel to the eld's direction exactly as it does with oppositely charged colloids under the in uence of a uniform electric eld or pedestrian dynamics in corridors. We also show how the system relax to such stationary state by using a suitable order parameter related to the particles segregation. Di erently from other pedestrian dynamics models, our model is not based on a Langevin-type equation. Our approach is totally stochastic and from this point of view, more fundamental and general to be extended to more types of models considering particles under counter ow. Our solution is obtained by both Monte Carlo simulations and numerical integration of partial di erential equations (PDE) from recurrence relation of the directed random walkers. The Monte Carlo simulations and the solutions of the PDE show a good agreement in all aspects analysed both qualitatively and quantitatively.

Processos estocasticos

Sistemas dinâmicos

Destilação

Método de Monte Carlo

Equações diferenciais parciais

Particle dynamic under counter flow

Relaxation to a stationary state

Segregation of particles

Distilation

Partial diferential equations

Monte Carlo

Ordenamento e destilação em um modelo estocástico de partículas interagentes sob contrafluxo

Stock, Eduardo Velasco

January 2016

Neste trabalho estudamos uma dinâmica estocástica de partículas de duas espécies baseada em células. Basicamente, incorporamos algumas inovações em um modelo unidimensional proposto e resolvido por R. da Silva et al. (Physica A, 2015), que considera que em um célula, na ausência de partículas da espécie contrária, a partícula vai pra frente com uma probabilidade p, que representaria um campo na direção longitudinal de um corredor e fica na própria célula com q=1-p. Contudo, essa probabilidade p é reduzida de acordo com a concentração de partículas contrárias. Nosso trabalho não apenas estendeu o problema pra duas dimensões como também incluiu aspectos relativos a colisão e o espalhamento para células vizinhas. Nossos resultados são divididos em duas situações: a) Espécie contrária permanece imóvel funcionando como obstáculos b) Espécie contrária em movimento. Na primeira situação podemos ver uma interessante transição na distribuição dos tempos de travessia em função das concentrações dos obstáculos, por monitorar a curtose da distribuição. Quando a espécie contrária se movimenta, vemos que o tempo de destilação entre as partículas (tempo para que as espécies estejam geograficamente separadas no corredor) depende do parâmetro ligado ao espalhamento transversal das partículas, parâmetro este, que não influencia no caso das partículas paradas. Finalmente nós colocamos as partículas em um sistema com condições periódicas de contorno. Neste caso, podemos observar o aparecimento de padrões de bandas longitudinais ao campo, exatamente como ocorrem em problemas de coloides carregados sob a ação de campos longitudinais e em modelos de pedestres em corredores. Mostramos como o sistema relaxa para tal tipo de estado estacionário utilizando um adequado parâmetro de ordem ligado a segregação das partículas. Nosso modelo, diferentemente dos modelos para pedestres, não se baseia em equações tipo Langevin. Nossa abordagem é totalmente estocástica e por esse ponto de vista ainda mais fundamental e geral, podendo ser estendida para mais modelos de partículas em fluxos contrários. Nossa solução vem tanto através de simulações Monte Carlo bem como soluções das equações diferenciais parciais que descrevem o sistema e que são oriundas das recorrências estabelecidas para os caminhantes aleatórios. As simulações Monte Carlo e soluções via EDP mostram boa concordância em todos os aspectos analisados, tanto qualitativa quanto quantitativamente. / In this work we study a stochastic dynamic of particles of two types based on cells. Basically we incorporate some innovations on a one-dimensional model proposed and solved by R. da Silva et al. (Physica A, 2015) which considers that in the absence of particles of the opposite species in the cell a particle goes toward the next cell with probability p and returns to the previous cell with probability q = 1 p. However this motion probability linearly decreases with the relative density of the contrary species. Our work not only expands the problem for two dimensions but also includes collision aspects by adding scattering to the neighbouring cells. Our results are divided into two di erent categories: a) One of the species remain xed in their places which means that such particles will work as obstacles; b) Both species can move in the environment. In the rst situation we can observe, by monitoring the kurtosis, that an interesting transition of the crossing time distribution arises as the concentration of the obstacles increases. When both species can move we can observe that the distillation time (spent time for the complete geographical separation of the species in the corridor) depends on the parameter related to the perpendicular scattering of the particles. This same parameter has shown no in uence over the time distributions in the rst situation. Finally we implement periodic boundary conditions in the eld's direction. In this case we are able to observe the arising of band patterns parallel to the eld's direction exactly as it does with oppositely charged colloids under the in uence of a uniform electric eld or pedestrian dynamics in corridors. We also show how the system relax to such stationary state by using a suitable order parameter related to the particles segregation. Di erently from other pedestrian dynamics models, our model is not based on a Langevin-type equation. Our approach is totally stochastic and from this point of view, more fundamental and general to be extended to more types of models considering particles under counter ow. Our solution is obtained by both Monte Carlo simulations and numerical integration of partial di erential equations (PDE) from recurrence relation of the directed random walkers. The Monte Carlo simulations and the solutions of the PDE show a good agreement in all aspects analysed both qualitatively and quantitatively.

Processos estocasticos

Sistemas dinâmicos

Destilação

Método de Monte Carlo

Equações diferenciais parciais

Particle dynamic under counter flow

Relaxation to a stationary state

Segregation of particles

Distilation

Partial diferential equations

Monte Carlo

Low-Velocity K-Shell Ionization Cross Sections for Protons, Deuterons and Alpha Particles Bombarding Thin Metal Targets

Rice, Roger Karl

05 1900

The purpose of this work was to examine the effect of the use the assumption κω2K/ΕCM «1 in calculating K-shell ionization cross sections in the plane wave Born approximation (PWBA) where κω2K is the observed binding energy of the K-shell and ECM is the energy of the incident particle in the center of mass system. Avoiding this assumption produces a threshold for ionization at Ecm = κω2K. Calculations employing the assumption, which leads to the use of approximate limits of integration, do not go to zero for even the .Lowest values of the incident energy.

K-shell ionization cross sections

K-shell x-ray production

plane wave Born approximation

perturbed stationary state theories

Cross sections (Nuclear physics)

Ordenamento e destilação em um modelo estocástico de partículas interagentes sob contrafluxo

Stock, Eduardo Velasco

January 2016

Neste trabalho estudamos uma dinâmica estocástica de partículas de duas espécies baseada em células. Basicamente, incorporamos algumas inovações em um modelo unidimensional proposto e resolvido por R. da Silva et al. (Physica A, 2015), que considera que em um célula, na ausência de partículas da espécie contrária, a partícula vai pra frente com uma probabilidade p, que representaria um campo na direção longitudinal de um corredor e fica na própria célula com q=1-p. Contudo, essa probabilidade p é reduzida de acordo com a concentração de partículas contrárias. Nosso trabalho não apenas estendeu o problema pra duas dimensões como também incluiu aspectos relativos a colisão e o espalhamento para células vizinhas. Nossos resultados são divididos em duas situações: a) Espécie contrária permanece imóvel funcionando como obstáculos b) Espécie contrária em movimento. Na primeira situação podemos ver uma interessante transição na distribuição dos tempos de travessia em função das concentrações dos obstáculos, por monitorar a curtose da distribuição. Quando a espécie contrária se movimenta, vemos que o tempo de destilação entre as partículas (tempo para que as espécies estejam geograficamente separadas no corredor) depende do parâmetro ligado ao espalhamento transversal das partículas, parâmetro este, que não influencia no caso das partículas paradas. Finalmente nós colocamos as partículas em um sistema com condições periódicas de contorno. Neste caso, podemos observar o aparecimento de padrões de bandas longitudinais ao campo, exatamente como ocorrem em problemas de coloides carregados sob a ação de campos longitudinais e em modelos de pedestres em corredores. Mostramos como o sistema relaxa para tal tipo de estado estacionário utilizando um adequado parâmetro de ordem ligado a segregação das partículas. Nosso modelo, diferentemente dos modelos para pedestres, não se baseia em equações tipo Langevin. Nossa abordagem é totalmente estocástica e por esse ponto de vista ainda mais fundamental e geral, podendo ser estendida para mais modelos de partículas em fluxos contrários. Nossa solução vem tanto através de simulações Monte Carlo bem como soluções das equações diferenciais parciais que descrevem o sistema e que são oriundas das recorrências estabelecidas para os caminhantes aleatórios. As simulações Monte Carlo e soluções via EDP mostram boa concordância em todos os aspectos analisados, tanto qualitativa quanto quantitativamente. / In this work we study a stochastic dynamic of particles of two types based on cells. Basically we incorporate some innovations on a one-dimensional model proposed and solved by R. da Silva et al. (Physica A, 2015) which considers that in the absence of particles of the opposite species in the cell a particle goes toward the next cell with probability p and returns to the previous cell with probability q = 1 p. However this motion probability linearly decreases with the relative density of the contrary species. Our work not only expands the problem for two dimensions but also includes collision aspects by adding scattering to the neighbouring cells. Our results are divided into two di erent categories: a) One of the species remain xed in their places which means that such particles will work as obstacles; b) Both species can move in the environment. In the rst situation we can observe, by monitoring the kurtosis, that an interesting transition of the crossing time distribution arises as the concentration of the obstacles increases. When both species can move we can observe that the distillation time (spent time for the complete geographical separation of the species in the corridor) depends on the parameter related to the perpendicular scattering of the particles. This same parameter has shown no in uence over the time distributions in the rst situation. Finally we implement periodic boundary conditions in the eld's direction. In this case we are able to observe the arising of band patterns parallel to the eld's direction exactly as it does with oppositely charged colloids under the in uence of a uniform electric eld or pedestrian dynamics in corridors. We also show how the system relax to such stationary state by using a suitable order parameter related to the particles segregation. Di erently from other pedestrian dynamics models, our model is not based on a Langevin-type equation. Our approach is totally stochastic and from this point of view, more fundamental and general to be extended to more types of models considering particles under counter ow. Our solution is obtained by both Monte Carlo simulations and numerical integration of partial di erential equations (PDE) from recurrence relation of the directed random walkers. The Monte Carlo simulations and the solutions of the PDE show a good agreement in all aspects analysed both qualitatively and quantitatively.

Processos estocasticos

Sistemas dinâmicos

Destilação

Método de Monte Carlo

Equações diferenciais parciais

Particle dynamic under counter flow

Relaxation to a stationary state

Segregation of particles

Distilation

Partial diferential equations

Monte Carlo

Comportement en temps long d'équations de type Vlasov : études mathématiques et numériques / Long time behavior of certain Vlasov equations : mathematics and numerics

Horsin, Romain

01 December 2017

Cette thèse porte sur le comportement en temps long de solutions d’équations de type Vlasov, principalement le modèle Vlasov-HMF. On s’intéresse en particulier au phénomène d’amortissement Landau, prouvé mathématiquement dans divers cadres, pour plusieurs équations de type Vlasov, comme l’équation de Vlasov-Poisson ou le modèle Vlasov-HMF, et présentant certaines analogies avec le phénomène d’amortissement non visqueux pour l’équation d’Euler 2D. Les résultats qui y sont décrits sont les suivants. Le premier est un théorème d’amortissement Landau pour des solutions numériques du modèle Vlasov-HMF, obtenues par discrétisation en temps de ce dernier via des méthodes de splitting. Nous prouvons en outre la convergence des schémas numériques. Le second est un théorème d’amortissment Landau pour des solutions du modéle Vlasov-HMF linéarisé autour d’états stationnaires inhomogènes. Ce théorème est accompagné de nombreuses simulations numériques destinées à étudier numériquement le cas non-linéaire, et semblant mettre en lumière de nouveaux phénomènes. Enfin, le dernier résultat porte sur la discrétisation en temps de l’équation d’Euler 2D par un intégrateur de Crouch-Grossman symplectique. Nous prouvons la convergence du schéma. / This thesis concerns the long time behavior of certain Vlasov equations, mainly the Vlasov- HMF model. We are in particular interested in the celebrated phenomenon of Landau damp- ing, proved mathematically in various frameworks, foar several Vlasov equations, such as the Vlasov-Poisson equation or the Vlasov-HMF model, and exhibiting certain analogies with the inviscid damping phenomenon for the 2D Euler equation. The results described in the document are the following.The first one is a Landau damping theorem for numerical solutions of the Vlasov-HMF model, constructed by means of time-discretizations by splitting methods. We prove more- over the convergence of the schemes. The second result is a Landau damping theorem for solutions of the Vlasov-HMF model linearized around inhomogeneous stationary states. We provide moreover a quite large amount of numerical simulations, which are designed to study numerically the nonlinear case, and which seem to show new phenomenons. The last result is the convergence of a scheme that discretizes in time the 2D Euler equation by means of a symplectic Crouch-Grossmann integrator.

Équations de type Vlasov

Équations d’Euler

Équations de transport

Amortissement Landau

État stationnaire

Méthodes de splitting

Méthodes semi-Lagrangiennes

Intégrateur symplectique

Intégrateur de Crouch-Grossman

Analyse d’erreur rétrograde

Systèmes hamiltoniens

Coordonnées action-angle

Vlasov equations

Euler equations

Transport equations

Landau damping

Stationary state

Splitting methods

Semi-Lagrangian methods

Symplectic integrator

Crouch-Grossman integrator

Backward error analysis

Hamiltonian systems

Angle-action variables

Indikace zemních spojení na venkovních vedeních / The Indication of Earth Faults in Overhead Lines

Pospíšil, Zdeněk

January 2015

This master´s thesis deals with the indication and localization of earth faults in overhead lines. Earth fault is the most frequently occurring type of fault in medium voltage overhead lines – it covers approx. 95% of all faults and is very difficult to indicate and localize them correctly and in time with currently available methods on the market. Therefore is very important to study earth fault and its indication, localization. The thesis consists of a theoretical and a practical part. The theoretical part deals with faults in overhead networks with different type of neutral grounding, mainly with one phase to the ground fault in the compensated, ungrounded, solidly grounded and via resistance grounded networks. Most of the theoretical part is dedicated to one phase to the ground fault in the compensated and ungrounded networks, where this type fault is called the earth fault. In the compensated and ungrounded networks is described in details behavior – voltage and current relations during both steady state and transient state earth fault. The theoretical part is further dedicated to detection methods of earth faults and their preconditions for use. There is described also in details the complete procedure of earth fault detection, which includes indication, unhealthy feeder determination and exact position or line section localization. End of the theoretical part is then focused on determination of accuracy requirements for measurement of basic quantities and computation of other parameters. The practical part deals with a work at medium distribution network model, which includes familiarization with the model, detailed verification of its functionality and behavior during the earth fault, obtaining faults records and algorithmization of methods: method of qu – diagram and method of first half - period, which are able to detect unhealthy feeder. This part of the thesis was put together based on a demand of company Mega, corp., which wanted to verify function of both above mentioned and by them not yet tested methods.

Stabilité pour des modèles de réseaux de neurones et de chimiotaxie / Stability for the models of neuronal network and chemotaxis

Weng, Qilong

29 September 2017

Cette thèse vise à étudier certains modèles biologiques dans le réseau neuronal et dans la chimiotaxie avec la méthode d’analyse spectrale. Afin de traiter les principaux problèmes, tels que l’existence et l’unicité des solutions et des états stationnaires ainsi que les comportements asymptotiques, le modèle linéaire ou linéarisé associé est considéré par l’aspect du spectre et des semi-groupes dans les espaces appropriés, puis la stabilité de modèle non linéaire suit. Plus précisément, nous commençons par une équation de courses-et-chutes linéaire dans la dimension d≥1 pour établir l’existence d’un état stationnaire unique, positif et normalisé et la stabilité exponentielle asymptotique dans l’espace L¹ pondéré basé sur la théorie de Kerin-Rutman avec quelques estimations du moment de la théorie cinétique. Ensuite, nous considérons le modèle du temps écoulé sous les hypothèses générales sur le taux de tir et nous prouvons l’unicité de l’état stationnaire et sa stabilité exponentielle non linéaire en cas sans ou avec délai au régime de connectivité faible de la théorie de l’analyse spectrale pour les semi-groupes. Enfin, nous étudions le modèle sous une hypothèse de régularité plus faible sur le taux de tir et l’existence de la solution ainsi que la même stabilité exponentielle sont généralement établies n’importe la prise en compte du délai ou non, au régime de connectivité faible ou forte. / This thesis is aimed to study some biological models in neuronal network and chemotaxis with the spectral analysis method. In order to deal with the main concerning problems, such as the existence and uniqueness of the solutions and steady states as well as the asymptotic behaviors, the associated linear or linearized model is considered from the aspect of spectrum and semigroups in appropriate spaces then the nonlinear stability follows. More precisely, we start with a linear runs-and-tumbles equation in dimension d≥1 to establish the existence of a unique positive and normalized steady state and the exponential asymptotic stability in weighted L¹ space based on the Krein-Rutman theory together with some moment estimates from kinetic theory. Then, we consider time elapsed model under general assumptions on the firing rate and prove the uniqueness of the steady state and its nonlinear exponential stability in case without or with delay in the weak connectivity regime from the spectral analysis theory for semigroups. Finally, we study the model under weaker regularity assumption on the firing rate and the existence of the solution as well as the same exponential stability are established generally no matter taking delay into account or not and no matter in weak or strong connectivity regime.

Théorie de l’analyse spectrale

Modèle de courses-Et-Chutes

Équations cinétiques

Processus de vitesse-Saut

Chimiotaxie

État stationnaire

Stabilité asymptotique

Hypocoercivité

Réseau de neurones

Dynamique du temps écoulé

Connectivité faible

Connectivité forte

Hypodissipativité

Convergence exponentielle

Spectral analysis theory

Runs-And-Tumbles model

Kinetic equations

Velocity-Jump processes

Chemotaxis

Stationary state

Asymptotic stability

Hypocoercivity

Neuron network

Time elapsed dynamics

Weak connectivity

Strong connectivity

Hypodissipativity

Exponential convergence

515