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1	Fourth-Order Problems with Mixed Dispersion Alves Do Nascimento Filho, Robson 29 June 2018 (has links) This thesis is devoted to the study the mixed dispersion fourth order nonlinear Schrodinger equations. Our main concern is standing wave solutions. Our approach is based on minimization methods with constraints. Under suitable conditions, we establish existence of minimizers and we investigate their qualitative properties, namely their sign, symmetry and decay at infinity as well as their uniqueness, nondegeneracy and orbital stability. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Analyse mathématique Fourth-Order, Mixed Dispersion
2	Matrix methods for computing Eigenvalues of Sturm-Liouville problems of order four Rattana, Amornrat, Böckmann, Christine January 2012 (has links) This paper examines and develops matrix methods to approximate the eigenvalues of a fourth order Sturm-Liouville problem subjected to a kind of fixed boundary conditions, furthermore, it extends the matrix methods for a kind of general boundary conditions. The idea of the methods comes from finite difference and Numerov's method as well as boundary value methods for second order regular Sturm-Liouville problems. Moreover, the determination of the correction term formulas of the matrix methods are investigated in order to obtain better approximations of the problem with fixed boundary conditions since the exact eigenvalues for q = 0 are known in this case. Finally, some numerical examples are illustrated. Finite difference method Numerov's method Boundary value methods Fourth order Sturm-Liouville problem Eigenvalues Mathematics
3	Numerical Computation for Nonlinear Beam Problems Tsai, Siang-Yu 04 July 2005 (has links) Beam problem is very important for engineering theoretically and practically. In this thesis we study such kind of nonlinear 4-th order ordiniary differential equations with nonlinear boundary conditions. The well-posedness of these boundary value problems will be discussed. Moreover, we will design different schemes to solve them, through differential equation, integral equation or minimization. Each type can further be discretized by finite difference, finite element or spectral method, etc. In the end we will compare all methods and find the best one. well-poseness beam nonlinearity numerical solution
4	Separating Computer Image Background and Foreground Via A Neural Network Lin, Di-ren 11 July 2000 (has links) None VQNN Likelihood Ratio Difference Picture Fourth-Order Moments LBG Neural Network
5	Exact solutions of massive gravity in three dimensions Chakhad, Mohamed 15 October 2009 (has links) In recent years, there has been an upsurge in interest in three-dimensional theories of gravity. In particular, two theories of massive gravity in three dimensions hold strong promise in the search for fully consistent theories of quantum gravity, an understanding of which will shed light on the problems of quantum gravity in four dimensions. One of these theories is the “old” third-order theory of topologically massive gravity (TMG) and the other one is a “new” fourth-order theory of massive gravity (NMG). Despite this increase in research activity, the problem of finding and classifying solutions of TMG and NMG remains a wide open area of research. In this thesis, we provide explicit new solutions of massive gravity in three dimensions and suggest future directions of research. These solutions belong to the Kundt class of spacetimes. A systematic analysis of the Kundt solutions with constant scalar polynomial curvature invariants provides a glimpse of the structure of the spaces of solutions of the two theories of massive gravity. We also find explicit solutions of topologically massive gravity whose scalar polynomial curvature invariants are not all constant, and these are the first such solutions. A number of properties of Kundt solutions of TMG and NMG, such as an identification of solutions which lie at the intersection of the full nonlinear and linearized theories, are also derived. / text Massive gravity in three dimensions Topologically massive gravity Fourth-order theory of massive gravity Kundt solutions
6	Dispersive Estimates of Schrodinger and Schrodinger-Like Equations in One Dimension Hill, Thomas 15 October 2020 (has links) No description available. Mathematics Schrodinger equation dispersive estimates fourth-order Wiener algebra one-dimensional
7	The Numerical Solution of Differential Equations by Third and Fourth Order Runge-Kutta Methods. Ebos, Frank 10 1900 (has links) An examination of third and fourth order Runge-Kutta methods which can be utilized to solve various ordinary differential equations is considered. / Thesis / Master of Science (MS)
8	Fourth order Multi-Time-Stepping Adams-Bashforth (MTSAB) scheme for NASA Glenn Research Center’s Broadband Aeroacoustic Stator Simulation (BASS) Code Allampalli, Vasanth 14 June 2010 (has links) No description available. Mechanical Engineering Multi-Time Step Adams-Bashforth scheme BASS code Fourth order
9	Blending using ODE swept surfaces with shape control and C1 continuity You, L.H., Ugail, Hassan, Tang, B.P., Jin, X., You, X.Y., Zhang, J.J. 20 April 2014 (has links) No / Surface blending with tangential continuity is most widely applied in computer-aided design, manufacturing systems, and geometric modeling. In this paper, we propose a new blending method to effectively control the shape of blending surfaces, which can also satisfy the blending constraints of tangent continuity exactly. This new blending method is based on the concept of swept surfaces controlled by a vector-valued fourth order ordinary differential equation (ODE). It creates blending surfaces by sweeping a generator along two trimlines and making the generator exactly satisfy the tangential constraints at the trimlines. The shape of blending surfaces is controlled by manipulating the generator with the solution to a vector-valued fourth order ODE. This new blending methods have the following advantages: (1) exact satisfaction of C1C1 continuous blending boundary constraints, (2) effective shape control of blending surfaces, (3) high computing efficiency due to explicit mathematical representation of blending surfaces, and (4) ability to blend multiple (more than two) primary surfaces.
10	A study of heteroclinic orbits for a class of fourth order ordinary differential equations Bonheure, Denis 09 December 2004 (has links) In qualitative theory of differential equations, an important role is played by special classes of solutions, like periodic solutions or solutions to some boundary value problems. When a system of ordinary differential equations has equilibria, i.e. constant solutions, whose stability properties are known, it is significant to search for connections between them by trajectories of solutions of the given system. These are called homoclinic or heteroclinic, according to whether they describe a loop based at one single equilibrium or they "start" and "end" at two distinct equilibria. This thesis is devoted to the study of heteroclinic solutions for a specific class of ordinary differential equations related to the Extended Fisher-Kolmogorov equation and the Swift-Hohenberg equation. These are semilinear fourth order bi-stable evolution equations which appear as mathematical models for problems arising in Mechanics, Chemistry and Biology. For such equations, the set of bounded stationary solutions is of great interest. These solve an autonomous fourth order equation. In this thesis, we focus on such equations having a variational structure. In that case, the solutions are critical points of an associated action functional defined in convenient functional spaces. We then look for heteroclinic solutions as minimizers of the action functional. Our main contributions concern existence and multiplicity results of such global and local minimizers in the case where the functional is defined from sign changing Lagrangians. The underlying idea is to impose conditions which imply a lower bound on the action over all admissible functions. We then combine classical arguments of the Calculus of Variations with careful estimates on minimizing sequences to prove the existence of a minimum. Heteroclinic solutions Homoclinic solutions Variational methods Swift-Hohenberg equation Extended Fisher-Kolmogorov equation Hamiltonian systems

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