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Combat modelling with partial differential equationsKeane, Therese Alison, Mathematics & Statistics, Faculty of Science, UNSW January 2009 (has links)
In Part I of this thesis we extend the Lanchester Ordinary Differential Equations and construct a new physically meaningful set of partial differential equations with the aim of more realistically representing soldier dynamics in order to enable a deeper understanding of the nature of conflict. Spatial force movement and troop interaction components are represented with both local and non-local terms, using techniques developed in biological aggregation modelling. A highly accurate flux limiter numerical method ensuring positivity and mass conservation is used, addressing the difficulties of inadequate methods used in previous research. We are able to reproduce crucial behaviour such as the emergence of cohesive density profiles and troop regrouping after suffering losses in both one and two dimensions which has not been previously achieved in continuous combat modelling. In Part II, we reproduce for the first time apparently complex cellular automaton behaviour with simple partial differential equations, providing an alternate mechanism through which to analyse this behaviour. Our PDE model easily explains behaviour observed in selected scenarios of the cellular automaton wargame ISAAC without resorting to anthropomorphisation of autonomous 'agents'. The insinuation that agents have a reasoning and planning ability is replaced with a deterministic numerical approximation which encapsulates basic motivational factors and demonstrates a variety of spatial behaviours approximating the mean behaviour of the ISAAC scenarios. All scenarios presented here highlight the dangers associated with attributing intelligent reasoning to behaviour shown, when this can be explained quite simply through the effects of the terms in our equations. A continuum of forces is able to behave in a manner similar to a collection of individual autonomous agents, and shows decentralised self-organisation and adaptation of tactics to suit a variety of combat situations. We illustrate the ability of our model to incorporate new tactics through the example of introducing a density tactic, and suggest areas for further research.
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Dinâmica de colisão de multipartículas: simulando a hidrodinâmica de fluidos complexos através de uma aproximação de partículas / Multiparticle collision dynamics: simulating the hydrodynamics of complex fluids through a particle approximationFigueiredo, David Oliveira de January 2014 (has links)
FIGUEIREDO, David de Oliveira. Dinâmica de colisão de multipartículas: simulando a hidrodinâmica de fluidos complexos através de uma aproximação de partículas. 2014. 78 f. Dissertação (Mestrado em Física) - Programa de Pós-Graduação em Física, Departamento de Física, Centro de Ciências, Universidade Federal do Ceará, Fortaleza, 2014. / Submitted by Edvander Pires (edvanderpires@gmail.com) on 2014-08-29T19:33:17Z
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Previous issue date: 2014 / Simulation techniques with a strategy based on particle dynamics are an interesting alternative approach in describing the behavior of complex fluids. In these systems, phenomena occur typically in the range of mesoscopic size (nanometers to micrometers), where the energies are of the order of the thermal energy kT. In many phenomena the microscopic detail of the interaction between the constituents of the system is crucial for the correct description of the physical processes associated, so that a "coarse-graining" approximation, used in a continuous description based on the Navier-Stokes is not appropriate. It is in this context that the method presented here becomes important. Introduced by Malevanets and Kapral in 1999, the stochastic rotation dynamics, or multiparticle collision dynamics, is a simulation method for mesoscopic fluids; which basically consists of alternating streaming and collisions steps in an ensemble of point particles. The collisions are performed by grouping the particles into cells, in which there is conservation of mass, momentum and energy, in addition to meeting the hydrodynamic equations and taking into account the thermal fluctuations of the system. In this work we aim at presenting the multiparticle collision dynamics, through a discussion of its details, features and how the implementation is done in numerical simulations. Moreover, we present some classical hydrodynamics results, obtained from the method presented in this work. / Técnicas de simulação com uma abordagem fundamentada na dinâmica de partículas são uma alternativa interessante na descrição do comportamento de fluidos complexos. Nesses sistemas, fenômenos ocorrem tipicamente na escala de tamanho mesoscópica (nanometros a micrometros), onde as energias são da ordem da energia térmica kT. Em diversos fenômenos o detalhe microscópico da interação entre os constituintes do sistema é de fundamental importância para a descrição correta dos processos físicos associados, de modo que uma aproximação do tipo "coarse-graining", usada em uma descrição contínua baseada na equação de Navier-Stokes, não é adequada. É neste contexto que o método aqui apresentado se faz importante. Introduzido por Malevanets e Kapral em 1999, a dinâmica de rotação estocástica (stochastic rotation dynamics) ou dinâmica de colisão de multipartículas (multiparticle collision dynamics), é um método de simulação para fluidos mesoscópicos que basicamente consiste em alternar etapas de fluxo (streaming) e colisões num ensemble de partículas pontuais. As colisões são realizadas agrupando as partículas em células, nas quais há conservação de massa, momento linear e energia, além de satisfazer as equações hidrodinâmicas e levar em conta as flutuações térmicas do sistema. Neste trabalho temos como objetivo a apresentação da dinâmica de colisão de multipartículas, através de uma discussão sobre seus detalhes, particularidades e como é feita a implementação em simulações numéricas. Além disso, apresentamos como exemplo alguns resultados clássicos da hidrodinâmica, obtidos a partir do método abordado neste trabalho.
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Aplicações do método das diferenças finitas de alta ordem na solução de problemas de convecção-difusão : Applications of high-order finite difference method in the solution of the convection-diffusion equation / Applications of high-order finite difference method in the solution of the convection-diffusion equationCampos, Marco Donisete de, 1976- 24 August 2018 (has links)
Orientador: Luiz Felipe Mendes de Moura / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-24T19:08:20Z (GMT). No. of bitstreams: 1
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Previous issue date: 2014 / Resumo: O presente trabalho tem como objetivo aplicar o método de diferenças finitas de alta ordem na solução de problemas bi e tridimensionais convectivo-difusivos transientes. As simulações numéricas foram realizadas para investigar, nos problemas lineares, o termo de dissipação viscosa na equação de transferência de calor bidimensional com ênfase, no caso tridimensional, na aplicação envolvendo troca de calor num canal retangular. Para problemas não lineares, o método de Newton para a linearização do termo convectivo foi usado para resolver a equação de Burgers bi e tridimensionais. O esquema desenvolvido mostrou-se simples, computacionalmente rápido, podendo ser aplicado para problemas bi e tridimensionais. Nas aplicações propostas, quando possível, as soluções analíticas disponíveis na revisão da literatura foram utilizadas para comparações com as soluções numéricas e validação do código, sendo a análise dos resultados feita a partir das normas L2 e L? / Abstract: The present study aims to apply the high-order Finite Difference Method to transient diffusive-convective problems in two and three dimensions. Numerical simulations have been undertaken to investigate, in the linear problems, the viscous dissipation term in the two-dimensional heat transfer equation with emphasis, in the three-dimensional case, on the application involving heat exchange in a rectangular channel. For nonlinear problems, the Newton's method for the linearization of the convective term was used for solving the two and three dimensional Burgers equation. This scheme is simple, computationally fast and can be applied for two or three-dimensional problems. For the proposed applications, whenever possible, the analytical solutions found in the literature review were used to compare with the numerical solutions. The analysis of results was done from the L2 and L? norms / Doutorado / Termica e Fluidos / Doutor em Engenharia Mecânica
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On the design and implementation of a hybrid numerical method for singularly perturbed two-point boundary value problemsNyamayaro, Takura T. A. January 2014 (has links)
>Magister Scientiae - MSc / With the development of technology seen in the last few decades, numerous solvers have been developed to provide adequate solutions to the problems that model different aspects of science and engineering. Quite often, these solvers are tailor-made for specific classes of problems. Therefore, more of such must be developed to accompany the growing need for mathematical models that help in the understanding of the contemporary world. This thesis treats two point boundary value singularly perturbed problems. The solution to this type of problem undergoes steep changes in narrow regions (called boundary or internal layer regions) thus rendering the classical numerical procedures inappropriate. To this end, robust numerical methods such as finite difference methods, in particular fitted mesh and fitted operator methods have extensively been used. While the former consists of transforming the continuous problem into a discrete one on a non-uniform mesh, the latter involves a special discretisation of the problem on a uniform mesh and are known to be more accurate. Both classes of methods are suitably designed to accommodate the rapid change(s) in the solution. Quite often, finite difference methods on piece-wise uniform meshes (of Shishkin-type) are adopted. However, methods based on such non-uniform meshes, though layer-resolving, are not easily extendable to higher dimensions. This work aims at investigating the possibility of capitalising on the advantages of both fitted mesh and fitted operator methods. Theoretical results are confirmed by extensive numerical simulations.
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Numerical solutions of weather derivatives and other incomplete market problemsBroni-Mensah, Edwin January 2012 (has links)
The valuation of weather derivatives is complex since the underlying temperature process has no negotiable price. This thesis introduces a selection of models for the valuation of weather derivative contracts, governed by a stochastic underlying temperature process. We then present a new weather pricing model, which is used to determine the fair hedging price of a weather derivative under the assumptions of mean self-financing. This model is then extended to incorporate a compensation (or market price of risk) awarded to investors who hold undiversifiable risks. This results in the derivation of a non-linear two-dimensional PDE, for which the numerical evaluation cannot be performed using standard finite-difference techniques. The numerical techniques applied in this thesis are based on a broad range of lattice based schemes, including enhancements to finite-differences, quadrature methods and binomial trees. Furthermore simulations of temperature processes are undertaken that involves the development of Monte Carlo based methods.
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Convergent Difference Schemes for Hamilton-Jacobi equationsDuisembay, Serikbolsyn 07 May 2018 (has links)
In this thesis, we consider second-order fully nonlinear partial differential equations of elliptic type. Our aim is to develop computational methods using convergent difference schemes for stationary Hamilton-Jacobi equations with Dirichlet and Neumann type boundary conditions in arbitrary two-dimensional domains. First, we introduce the notion of viscosity solutions in both continuous and discontinuous frameworks. Next, we review Barles-Souganidis approach using monotone, consistent, and stable schemes. In particular, we show that these schemes converge locally uniformly to the unique viscosity solution of the first-order Hamilton-Jacobi equations under mild assumptions. To solve the scheme numerically, we use Euler map with some initial guess. This iterative method gives the viscosity solution as a limit. Moreover, we illustrate our numerical approach in several two-dimensional examples.
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Efficient and accurate numerical methods for two classes of PDEs with applications to quasicrystalsDuo Cao (8718126) 17 April 2020 (has links)
This dissertation is a summary of the graduate study in the past few years. In first part, we develop efficient spectral methods for the spectral fractional Laplacian equation and parabolic PDEs with spectral fractional Laplacian on rectangular domains. The key idea is to construct eigenfunctions of discrete Laplacian (also referred to Fourier-like basis) by using the Fourierization method. Under this basis, the nonlocal fractional Laplacian operator can be trivially evaluated, leading to very efficient algorithms for PDEs involving spectral fractional Laplacian. We provide a rigorous error analysis for the proposed methods, as well as ample numerical results to show their effectiveness.<div><br>In second part, we propose a method suitable for the computation of quasiperiodic interface, and apply it to simulate the interface between ordered phases in Lifschitz-Petrich model, which can be quasiperiodic. The function space, initial and boundary conditions are carefully chosen such that it fix the relative orientation and displacement, and we follow a gradient flow to let the interface and its optimal structure. The gradient flow is discretized by the scalar auxiliary variable (SAV) approach in time, and spectral method in space using quasiperiodic Fourier series and generalized Jacobi<br>polynomials. We use the method to study interface between striped, hexagonal and dodecagonal phases, especially when the interface is quasiperiodic. The numerical examples show that our method is efficient and accurate to successfully capture the interfacial structure.</div>
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Numerical heat transfer studies and test rig preparation on a gas turbine nozzle guide vaneKhorsand, Khashayar January 2014 (has links)
Heat transfer study on gas turbine blades is very important due to the resultant increase in cycle thermal efficiency. This study is focused on the heat transfer effects on a reference nozzle guide vane and test rig component preparation in heat and power technology division at KTH. In order to prepare the current test rig for heat transfer experiments, some feature should be changed in the current layout to give a nearly instant temperature rise for heat transfer measurement. The heater mesh component is the main component to be added to the current test rig. Some preliminary design parameters were set and the necessary power for the heater mesh to achieve required step temperature rise was calculated. For the next step, it is needed to estimate the heat transfer coefficient and the other parameters for study on the reference blade using numerical methods. Boundary layer analysis is very important in heat transfer modeling so to model the reference blade heat transfer and boundary layer properties, a 2D boundary layer code TEXSTAN is used and the velocity distribution around the vane was set to an input dataset file. After elements refinement to ensure the numerical accuracy of TEXSTAN code, various turbulence modeling was check to predict the heat transfer coefficient and boundary layer assessments. It was concluded from TEXTAN calculations that both suction and pressure side have transition flow while for the suction side it was predicted that the flow regime at trailing edge is fully turbulent. Based on the Abu-Ghannam –Shaw Transition model and by the aid of shape factor data, momentum Reynolds number and various boundary layer properties, it was concluded that the pressure side remains in transient region.
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Construction and analysis of exponential time differencing methods for the robust simulation of ecological modelsFarah, Gassan Ali Mohamed Osman January 2021 (has links)
>Magister Scientiae - MSc / In this thesis, we consider some interesting mathematical models arising in
ecology. Our focus is on the exploration of robust numerical solvers which are
applicable to models arising in mathematical ecology. To begin with, we consider
a simple but nonlinear second-order time-dependent partial differential
equation, namely, the Allen-Cahn equation. We discuss the construction of a
class of exponential time differencing methods to solve this particular problem.
This is then followed by a discussion on the extension of this approach
to solve a more difficult fourth-order time-dependent partial differential equation,
namely, Kuramoto-Sivashinsky equation. This equation is nonlinear.
Further applications include the extension of this approach to solve a complex
predator-prey system which is a system of fourth-order time-dependent
non-linear partial differential equations. For each of these differential equation
models, we presented numerical simulation results. / 2025
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Constructing Numerical Methods For Solving The Guiding Equation In Bohmian MechanicsRobert, Nilsson January 2021 (has links)
The aim of this thesis was to simulate a part of a proposed experiment by Lev Vaidman by using Bohmian mechanics. To do this a numerical method for solving the Schrödinger equation and theguiding equation was created, with several ways of making the simulation more efficient.To make the simulation work more efficiently the Schrödinger equation was applied to only a small region of the whole setup. This region followed the wavefunction of significant values and could change size during the simulation. A beam splitter was constructed in the form of a thin potential barrier. The beam splitter was tested to verify that the reflected and transmitted angles agreed with expectations. A virtual detector was constructed and used for the calibration of the beam splitter to determine which potential resulted in dividing the wave packet into two wave packets of equal intensity. A fixed angle mirror was used for testing the reflection of a wave packet for the reflected angle and concluded that it agreed with the expectations for it. Testing a time dependent mirror for different frequencies and amplitudes was performed, with the result that the numerical method could be used to determine the particles’ trajectories. These results were used to construct a larger setup that was a small part of Vaidman’s proposed experiment. These setups were done in several version. All setups had one wave packet that went through one beam splitter and separated into two wave packets. These two wave packets reflected at two mirrors with different frequencies and then interfered with each other at either free space or at another beam splitter. The result of the simulation of these setups was that the particles’ trajectories could be calculated with the guiding equation. / Syftet med denna avhandling var att simulera en del av det föreslagna experimentet av Lev Vaidman med hjälp av Bohmsk mekanik. För att göra detta skapades en numerisk metod för att lösa Schrödingerekvationen och den ledande ekvationen, ”the guiding equation”, med flera sätt att effektivisera simuleringen. För att effektivisera simuleringen tillämpades Schrödingerekvationen på endast en liten region i hela uppställningen. Denna region följde vågfunktionen med betydande värden och kunde ändra storlek under simuleringen.En stråldelare konstruerades i form av en tunn potentialbarriär. Stråldelaren testades för att verifiera attde reflekterade och överförda vinklarna överensstämde med förväntningarna. En virtuell detektorkonstruerades och användes för kalibrering av stråldelaren för att bestämma vilken potential som resulterade i att vågpaketet delades in i två vågpaket med samma intensitet.En spegel med fast vinkel användes för att testa reflektionen av ett vågpaket för den reflekterade vinkeln och kom fram till att den överensstämde med förväntningarna för den. Att testa en tidsberoendespegel för olika frekvenser och amplituder utfördes med resultatet att den numeriska metoden kunde användas för att bestämma partiklarnas banor. Dessa resultat användes för att konstruera en större uppställning av ett experiment som var en liten delav Vaidmans föreslagna experiment. Dessa uppställningar gjordes i flera versioner. Alla uppställningar hade ett vågpaket som gick igenom en stråldelare och separerades i två vågpaket. Dessa två vågpaket reflekterades vid två speglar med olika frekvenser och interfererade sedan varandra antingen i en tom rymd eller vid en annan stråldelare. Resultatet av simuleringen av dessa inställningar var att partiklarnas banor kunde beräknas med ledande ekvation.
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