Derivação e solução de equações modelo da dinâmica de gases rarefeitos

Cabrera, Luciana Chimendes

January 2003

Neste trabalho, duas equações modedlo na área da dinâmica de gases rarefeitos, são derivadas a partir de algumas soluções exatas da equação linearizada de Boltzmann homogênea e não homogênea. Em adição, uma versão analítca do método de ordenadas discretas é usado para resolver problemas clássicos nesta área, descritos pelo "Modelo S". Resultados numéricos são apresentados para os problemas de fluxo de Couette, fluxo de Poiseuille, "Creep" Térmico, Deslizamento Térmico e problema de Kramers.

Equação linearizada de Boltzman

Métodos de ordenadas discretas

Gases rarefeitos

Оптимизација CFD симулације на групама вишејезгарних хетерогених архитектура / Optimizacija CFD simulacije na grupama višejezgarnih heterogenih arhitektura / Optimization of CFD simulations on groups of many-core heterogeneous architectures

Tekić Jelena

07 October 2019

<p>Предмет&nbsp; истраживања&nbsp; тезе&nbsp; је&nbsp; из области&nbsp; паралелног&nbsp; програмирања,<br />имплементација&nbsp; CFD&nbsp; (Computational Fluid&nbsp; Dynamics)&nbsp; методе&nbsp; на&nbsp; више<br />хетерогених&nbsp; вишејезгарних&nbsp; уређаја истовремено.&nbsp; У&nbsp; раду&nbsp; је&nbsp; приказано<br />неколико&nbsp; алгоритама&nbsp; чији&nbsp; је&nbsp; циљ убрзање&nbsp; CFD&nbsp; симулације&nbsp; на персоналним&nbsp; рачунарима.&nbsp; Показано је&nbsp; да&nbsp; описано&nbsp; решење&nbsp; постиже задовољавајуће&nbsp; перформансе&nbsp; и&nbsp; на HPC&nbsp; уређајима&nbsp; (Тесла&nbsp; графичким картицама).&nbsp; Направљена&nbsp; је симулација&nbsp; у&nbsp; микросервис архитектури&nbsp; која&nbsp; је&nbsp; портабилна&nbsp; и флексибилна и додатно олакшава рад на персоналним рачунарима.</p> / <p>Predmet&nbsp; istraživanja&nbsp; teze&nbsp; je&nbsp; iz oblasti&nbsp; paralelnog&nbsp; programiranja,<br />implementacija&nbsp; CFD&nbsp; (Computational Fluid&nbsp; Dynamics)&nbsp; metode&nbsp; na&nbsp; više<br />heterogenih&nbsp; višejezgarnih&nbsp; uređaja istovremeno.&nbsp; U&nbsp; radu&nbsp; je&nbsp; prikazano<br />nekoliko&nbsp; algoritama&nbsp; čiji&nbsp; je&nbsp; cilj ubrzanje&nbsp; CFD&nbsp; simulacije&nbsp; na personalnim&nbsp; računarima.&nbsp; Pokazano je&nbsp; da&nbsp; opisano&nbsp; rešenje&nbsp; postiže zadovoljavajuće&nbsp; performanse&nbsp; i&nbsp; na HPC&nbsp; uređajima&nbsp; (Tesla&nbsp; grafičkim karticama).&nbsp; Napravljena&nbsp; je simulacija&nbsp; u&nbsp; mikroservis arhitekturi&nbsp; koja&nbsp; je&nbsp; portabilna&nbsp; i fleksibilna i dodatno olakšava rad na personalnim računarima.</p> / <p>The&nbsp; case&nbsp; study&nbsp; of&nbsp; this&nbsp; dissertation belongs&nbsp; to&nbsp; the&nbsp; field&nbsp; of&nbsp; parallel programming,&nbsp; the&nbsp; implementation&nbsp; of CFD&nbsp; (Computational&nbsp; Fluid&nbsp; Dynamics) method&nbsp; on&nbsp; several&nbsp; heterogeneous multiple&nbsp; core&nbsp; devices&nbsp; simultaneously. The&nbsp; paper&nbsp; presents&nbsp; several&nbsp; algorithms aimed&nbsp; at&nbsp; accelerating&nbsp; CFD&nbsp; simulation on common computers. Also it has been shown&nbsp; that&nbsp; the&nbsp; described&nbsp; solution achieves&nbsp; satisfactory&nbsp; performance&nbsp; on<br />HPC&nbsp; devices&nbsp; (Tesla&nbsp; graphic&nbsp; cards). Simulation is&nbsp; created&nbsp;&nbsp;&nbsp; in&nbsp; micro-service architecture that is portable and flexible and&nbsp; makes&nbsp; it&nbsp; easy&nbsp; to&nbsp; test&nbsp; CFD<br />simulations on common computers.</p>

Soot accumulation and combustion in porous media

Ochi, Fumihiro, Yamamoto, Kazuhiro

12 1900

No description available.

LATTICE BOLTZMAN METHOD

COMBUSTION

POROUS MEDIA

DIESEL PARTICULATE FILTER

SOOT

Derivação e solução de equações modelo da dinâmica de gases rarefeitos

Cabrera, Luciana Chimendes

January 2003

Neste trabalho, duas equações modedlo na área da dinâmica de gases rarefeitos, são derivadas a partir de algumas soluções exatas da equação linearizada de Boltzmann homogênea e não homogênea. Em adição, uma versão analítca do método de ordenadas discretas é usado para resolver problemas clássicos nesta área, descritos pelo "Modelo S". Resultados numéricos são apresentados para os problemas de fluxo de Couette, fluxo de Poiseuille, "Creep" Térmico, Deslizamento Térmico e problema de Kramers.

Equação linearizada de Boltzman

Métodos de ordenadas discretas

Gases rarefeitos

Derivação e solução de equações modelo da dinâmica de gases rarefeitos

Cabrera, Luciana Chimendes

January 2003

Neste trabalho, duas equações modedlo na área da dinâmica de gases rarefeitos, são derivadas a partir de algumas soluções exatas da equação linearizada de Boltzmann homogênea e não homogênea. Em adição, uma versão analítca do método de ordenadas discretas é usado para resolver problemas clássicos nesta área, descritos pelo "Modelo S". Resultados numéricos são apresentados para os problemas de fluxo de Couette, fluxo de Poiseuille, "Creep" Térmico, Deslizamento Térmico e problema de Kramers.

Equação linearizada de Boltzman

Métodos de ordenadas discretas

Gases rarefeitos

Semi-analytical Solution for Multiphase Fluid Flow Applied to CO2 Sequestration in Geologic Porous Media

Mohamed, Ahmed

16 December 2013

The increasing concentration of CO_(2) has been linked to global warming and changes in climate. Geologic sequestration of CO_(2) in deep saline aquifers is a proposed greenhouse gas mitigation technology with potential to significantly reduce atmospheric emissions of CO_(2). Feasibility assessments of proposed sequestration sites require realistic and computationally efficient models to simulate the subsurface pressure response and monitor the injection process, and quantify the risks of leakage if there is any. This study investigates the possibility of obtaining closed form expressions for spatial distribution of CO_(2) injected in brine aquifers and gas reservoirs. Four new semi-analytical solutions for CO_(2) injection in brine aquifers and gas reservoirs are derived in this dissertation. Both infinite and closed domains are considered in the study. The first solution is an analysis of CO_(2) injection into an initially brine-filled infinite aquifer, exploiting self–similarity and matched asymptotic expansion. The second is an expanding to the first solution to account for CO_(2) injection into closed domains. The third and fourth solutions are analyzing the CO_(2) injection in infinite and closed gas reservoirs. The third and fourth solutions are derived using Laplace transform. The brine aquifer solutions accounted for both Darcyian and non-Darcyian flow, while, the gas reservoir solutions considered the gas compressibility variations with pressure changes. Existing analytical solutions assume injection under constant rate at the wellbore. This assumption is problematic because injection under constant rate is hard to maintain, especially for gases. The modeled injection processes in all aforementioned solutions are carried out under constant pressure injection at the wellbore (i.e. Dirichlet boundary condition). One major difficulty in developing an analytical or semi-analytical solution involving injection of CO_(2) under constant pressure is that the flux of CO_(2) at the wellbore is not known. The way to get around this obstacle is to solve for the pressure wave first as a function of flux, and then solve for the flux numerically, which is subsequently plugged back into the pressure formula to get a closed form solution of the pressure. While there is no simple equation for wellbore flux, our numerical solutions show that the evolution of flux is very close to a logarithmic decay with time. This is true for a large range of the reservoir and CO_(2) properties. The solution is not a formation specific, and thus is more general in nature than formation-specific empirical relationships. Additionally, the solution then can be used as the basis for designing and interpreting pressure tests to monitor the progress of CO_(2) injection process. Finally, the infinite domain solution is suitable to aquifers/reservoirs with large spatial extent and low permeability, while the closed domain solution is applicable to small aquifers/reservoirs with high permeability.

Semi-Analytical solutions

Multiphase Fluid Flow

Carbon Dioxide Sequestration

Boltzman Transform

Matched Asymptotic Expansion

Laplace Transform

Tuning the Transport Properties of Layered Materials for Thermoelectric Applications using First-Principles Calculations

Saeed, Yasir

11 May 2014

Thermoelectric materials can convert waste heat into electric power and thus provide a way to reduce the dependence on fossil fuels. Our aim is to model the underlying materials properties and, in particular, the transport as controlled by electrons and lattice vibrations. The goal is to develop an understanding of the thermoelectric properties of selected materials at a fundamental level. The structural, electronic, optical, and phononic properties are studied in order to tune the transport, focusing on KxRhO2, NaxRhO2, PtSb2 and Bi2Se3. The investigations are based on density functional theory as implemented in the all electron linearized augmented plane wave plus local orbitals WIEN2k and pseudo potential Quantum-ESPRESSO codes. The thermoelectric properties are derived from Boltzmann transport theory under the constant relaxation time approximation, using the BoltzTraP code. We will discuss first the changes in the electronic band structure under variation of the cation concentration in layered KxRhO2 in the 2H phase and NaxRhO2 in the 3R phase. We will also study the hydrated phase. The deformations of the RhO6 octahedra turn out to govern the thermoelectric properties, where the high Seebeck coefficient results from ”pudding mold" bands. We investigate the thermoelectric properties of electron and hole doped PtSb2, which is not a layered material but shares “pudding mold" bands. PtSb2 has a high Seebeck coefficient at room temperature, which increases significantly under As alloying by bandgap opening and reduction of the lattice thermal conductivity. Bi2Se3 (bulk and thin film) has a larger bandgap then the well-known thermoelectric material Bi2Te3, which is important at high temperature. The structural stability, electronic structure, and transport properties of one to six quintuple layers of Bi2Se3 will be discussed. We also address the effect of strain on a single quintuple layer by phonon band structures. We will analyze the electronic and transport properties of Tl-doped Bi2Se3 under strain, focusing on the giant Rashba spin splitting (Tl doping breaks the inversion symmetry in Bi2Se3) and its dependence on biaxial tensile and compressive strain.

Transport properties

First-principles

Density Functional Theory

Boltzman Theory

Bandgap

Layered Materials

The Total Acquisition Number of the Randomly Weighted Path

Godbole, Anant, Kelley, Elizabeth, Kurtz, Emily, Pralat, Pawel, Zhang, Yiguang

01 January 2017

There exists a significant body of work on determining the acquisition number at(G) of various graphs when the vertices of those graphs are each initially assigned a unit weight. We determine properties of the acquisition number of the path, star, complete, complete bipartite, cycle, and wheel graphs for variations on this initial weighting scheme, with the majority of our work focusing on the expected acquisition number of randomly weighted graphs. In particular, we bound the expected acquisition number E(at(Pn)) of the n-path when n distinguishable "units" of integral weight, or chips, are randomly distributed across its vertices between 0.242n and 0.375n. With computer support, we improve it by showing that E(at(Pn)) lies between 0.29523n and 0.29576n. We then use subadditivity to show that the limiting ratio lim E(at(Pn))/n exists, and simulations reveal more exactly what the limiting value equals. The Hoeffding-Azuma inequality is used to prove that the acquisition number is tightly concentrated around its expected value. Additionally, in a different context, we offer a non-optimal acquisition protocol algorithm for the randomly weighted path and exactly compute the expected size of the resultant residual set.

depoissonization

poissonization

total acquisition number

Mathematics and Statistics

An Optimizing Code Generator for a Class of Lattice-Boltzmann Computations

Pananilath, Irshad Muhammed

January 2014

Lattice-Boltzmann method(LBM), a promising new particle-based simulation technique for complex and multiscale fluid flows, has seen tremendous adoption in recent years in computational fluid dynamics. Even with a state-of-the-art LBM solver such as Palabos, a user still has to manually write his program using the library-supplied primitives. We propose an automated code generator for a class of LBM computations with the objective to achieve high performance on modern architectures. Tiling is a very important loop transformation used to improve the performance of stencil computations by exploiting locality and parallelism. In the first part of the work, we explore diamond tiling, a new tiling technique to exploit the inherent ability of most stencils to allow tile-wise concurrent start. This enables perfect load-balance during execution and reduces the frequency of synchronization required. Few studies have looked at time tiling for LBM codes. We exploit a key similarity between stencils and LBM to enable polyhedral optimizations and in turn time tiling for LBM. Besides polyhedral transformations, we also describe a number of other complementary transformations and post processing necessary to obtain good parallel and SIMD performance on modern architectures. We also characterize the performance of LBM with the Roofline performance model. Experimental results for standard LBM simulations like Lid Driven Cavity, Flow Past Cylinder, and Poiseuille Flow show that our scheme consistently outperforms Palabos–on average by3 x while running on 16 cores of a n Intel Xeon Sandy bridge system. We also obtain a very significant improvement of 2.47 x over the native production compiler on the SPECLBM benchmark.

Lattice-Boltzmann Computations

Computational Fluid Dynamics

Tiling Stencil Computations

Single Instruction Multiple Data (SIMD)

Parallel Computers

Parallel Processing

Loop Transformations

Lattice-Boltzman Method (LBM)

Lattice Boltzman Method

Lattice-Boltzmann Equation

Computer Science

Etude de la méthode de Boltzmann sur réseau pour la segmentation d'anévrismes cérébraux / Study of the lattice Boltzmann method application to cerebral aneurysm segmentation

Wang, Yan

25 July 2014

L'anévrisme cérébral est une région fragile de la paroi d'un vaisseau sanguin dans le cerveau, qui peut se rompre et provoquer des saignements importants et des accidents vasculaires cérébraux. La segmentation de l'anévrisme cérébral est une étape primordiale pour l'aide au diagnostic, le traitement et la planification chirurgicale. Malheureusement, la segmentation manuelle prend encore une part importante dans l'angiographie clinique et elle est devenue couteuse en temps de traitement étant donné la gigantesque quantité de données générées par les systèmes d'imagerie médicale. Les méthodes de segmentation automatique d'image constituent un moyen essentiel pour faciliter et accélérer l'examen clinique et pour réduire l'interaction manuelle et la variabilité inter-opérateurs. L'objectif principal de ce travail de thèse est de développer des méthodes automatiques pour la segmentation et la mesure des anévrismes. Le présent travail de thèse est constitué de trois parties principales. La première partie concerne la segmentation des anévrismes géants qui contiennent à la fois la lumière et le thrombus. La méthode consiste d'abord à extraire la lumière et le thrombus en utilisant une procédure en deux étapes, puis à affiner la forme du thrombus à l'aide de la méthode des courbes de niveaux. Dans cette partie, la méthode proposée est également comparée à la segmentation manuelle, démontrant sa bonne précision. La deuxième partie concerne une approche LBM pour la segmentation des vaisseaux dans des images 2D+t et de l'anévrisme cérébral dans les images en 3D. La dernière partie étudie un modèle de segmentation 4D en considérant les images 3D+t comme un hypervolume 4D et en utilisant un réseau LBM D4Q81, dans lequel le temps est considéré de la même manière que les trois autres dimensions pour la définition des directions de mouvement des particules dans la LBM, considérant les données 3D+t comme un hypervolume 4D et en utilisant un réseau LBM D4Q81. Des expériences sont réalisées sur des images synthétiques d'hypercube 4D et d'hypersphere 4D. La valeur de Dice sur l'image de l'hypercube avec et sans bruit montre que la méthode proposée est prometteuse pour la segmentation 4D et le débruitage. / Cerebral aneurysm is a fragile area on the wall of a blood vessel in the brain, which can rupture and cause major bleeding and cerebrovascular accident. The segmentation of cerebral aneurysm is a primordial step for diagnosis assistance, treatment and surgery planning. Unfortunately, manual segmentation is still an important part in clinical angiography but has become a burden given the huge amount of data generated by medical imaging systems. Automatic image segmentation techniques provides an essential way to easy and speed up clinical examinations, reduce the amount of manual interaction and lower inter operator variability. The main purpose of this PhD work is to develop automatic methods for cerebral aneurysm segmentation and measurement. The present work consists of three main parts. The first part deals with giant aneurysm segmentation containing lumen and thrombus. The methodology consists of first extracting the lumen and thrombus using a two-step procedure based on the LBM, and then refining the shape of the thrombus using level set technique. In this part the proposed method is also compared with manual segmentation, demonstrating its good segmentation accuracy. The second part concerns a LBM approach to vessel segmentation in 2D+t images and to cerebral aneurysm segmentation in 3D medical images through introducing a LBM D3Q27 model, which allows achieving a good segmentation and high robustness to noise. The last part investigates a true 4D segmentation model by considering the 3D+t data as a 4D hypervolume and using a D4Q81 lattice in LBM where time is considered in the same manner as for other three dimensions for the definition of particle moving directions in the LBM model.

Imagerie médicale

Angiographie

Anévrisme cérébral

Segmentation de thrombus

Méthode de Boltzman sur réseau

Détection de mouvement

Segmentation 4D

Segmentation automatique d'image

Medical Imaging

Angiography

Cerebral aneurysm

Aneurysm segmentation

Thrombus segmentation

Maticce Boltzman method

Movement detection

4D segmentation

Automatic image segmentation

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