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Author: Sathyanarayanan Chandramouli
Publisher:
ISBN:
Category : Mathematics
Languages : en
Pages : 0
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In this thesis, we develop and study two distinct problems in the field of nonlinear waves. The first part of the thesis is connected to the development of a computational algorithm that preserves underlying structure of the simulated initial boundary value problem in the form of multiple global conservation laws or dissipation rate equations. \\\\begin{itemize}\\\\item The time-dependent spectral renormalization (TDSR) method was introduced by Cole and Musslimani as a viable method to numerically solve initial boundary value problems. An important and novel aspect of the TDSR scheme is its ability to incorporate physics in the form of conservation laws or dissipation rate equations. However, the method was restricted to enforce the conservation or dissipation rate of just one quantity. The present work significantly extends the computational features of the algorithm with the (i) incorporation of multiple conservation laws and/or dissipation rate equations, (ii) ability to enforce versatile boundary conditions, and (iii) higher-order time integration strategies. The TDSR method is applied on several prototypical evolution equations of physical significance. Examples include the Korteweg-de Vries (KdV), multi-dimensional nonlinear Schr\\\\"odinger (NLS) and the Allen-Cahn equations. The work was published in Nonlinearity \\\\cite{chandramouli2022time}. \\\\end{itemize} The second half of the thesis identifies a broad class of novel, \\\\textit{non-centered} Riemann problems in optical media with externally imposed gain and loss distributions. Thereafter, we shed light on some unique features that arise from step-like distributions in such spatially inhomogeneous media. Our work thus is an important contribution to the field of non-Hermitian dispersive hydrodynamics. \\\\begin{itemize} \\\\item Dispersive hydrodynamics, the study of nonlinear dispersive wave dynamics in fluid-like media, is an active research area that combines mathematical analysis with computational and laboratory experiments. To date, most of the research in this area has been focused on wave phenomena in (i) bulk media, in which case the underlying governing equations are of constant coefficients type, or (ii) inhomogeneous environments, where now the evolution equations contain, for example, a real-valued external potential. In the latter case, the presence of inhomogeneity (in general) hinders the formulation of a Riemann problem due to the lack of plane wave-type solutions of constant intensity (or density). However such waves can exist in non-Hermitian media, as was demonstrated for the nonlinear Schrödinger (NLS) equation with a Wadati-type complex external potential. Inspired by the above-mentioned discussions, in this paper, the notion of non-Hermitian dispersive hydrodynamics and its associated non-Hermitian Riemann problems are introduced. Starting from the defocusing (repulsive) NLS equation in the presence of generic smooth complex external potentials, a new set of hydrodynamic-like equations are obtained. They differ from their classical counterparts (without an external potential), by the presence of additional source terms that alter the density and momentum equations. When restricted to a class of Wadati-type complex potentials, this new non-Hermitian hydrodynamic system admits constant intensity/density solutions. This in turn, allows one to formulate an exact centered (or non-centered) Riemann problem involving a step-like initial condition that connects two exact constant density states. A broad class of non-Hermitian potentials that lead to modulationally stable constant intensity states are identified. These results are subsequently used to numerically solve the associated non-Hermitian Riemann problem for various initial conditions. Due to the lack of translation symmetry, the resulting long-time dynamics show a strong dependence on the location of the step relative to the gain-loss distribution. This is in sharp contrast to the classical NLS Riemann problem (in the absence of potential), where the dynamics are generally independent of the step location. This fact leads to {a diverse array of} wave pattern dynamics that are otherwise absent. In particular, various novel gain-loss generated near-field features are observed, which in turn drive the optical flows in the far-field. {These far-field non-Hermitian counter-flows could be comprised of various rich nonlinear wave phenomena, including DSW-DSW, DSW-rarefaction, and soliton-DSW interactions. A manuscript containing the results has been submitted to Nonlinearity \\\\cite{chandramouli2023nonHermitian}.} \\\\end{itemize}
Author: Sathyanarayanan Chandramouli
Publisher:
ISBN:
Category : Mathematics
Languages : en
Pages : 0
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Book Description
In this thesis, we develop and study two distinct problems in the field of nonlinear waves. The first part of the thesis is connected to the development of a computational algorithm that preserves underlying structure of the simulated initial boundary value problem in the form of multiple global conservation laws or dissipation rate equations. \\\\begin{itemize}\\\\item The time-dependent spectral renormalization (TDSR) method was introduced by Cole and Musslimani as a viable method to numerically solve initial boundary value problems. An important and novel aspect of the TDSR scheme is its ability to incorporate physics in the form of conservation laws or dissipation rate equations. However, the method was restricted to enforce the conservation or dissipation rate of just one quantity. The present work significantly extends the computational features of the algorithm with the (i) incorporation of multiple conservation laws and/or dissipation rate equations, (ii) ability to enforce versatile boundary conditions, and (iii) higher-order time integration strategies. The TDSR method is applied on several prototypical evolution equations of physical significance. Examples include the Korteweg-de Vries (KdV), multi-dimensional nonlinear Schr\\\\"odinger (NLS) and the Allen-Cahn equations. The work was published in Nonlinearity \\\\cite{chandramouli2022time}. \\\\end{itemize} The second half of the thesis identifies a broad class of novel, \\\\textit{non-centered} Riemann problems in optical media with externally imposed gain and loss distributions. Thereafter, we shed light on some unique features that arise from step-like distributions in such spatially inhomogeneous media. Our work thus is an important contribution to the field of non-Hermitian dispersive hydrodynamics. \\\\begin{itemize} \\\\item Dispersive hydrodynamics, the study of nonlinear dispersive wave dynamics in fluid-like media, is an active research area that combines mathematical analysis with computational and laboratory experiments. To date, most of the research in this area has been focused on wave phenomena in (i) bulk media, in which case the underlying governing equations are of constant coefficients type, or (ii) inhomogeneous environments, where now the evolution equations contain, for example, a real-valued external potential. In the latter case, the presence of inhomogeneity (in general) hinders the formulation of a Riemann problem due to the lack of plane wave-type solutions of constant intensity (or density). However such waves can exist in non-Hermitian media, as was demonstrated for the nonlinear Schrödinger (NLS) equation with a Wadati-type complex external potential. Inspired by the above-mentioned discussions, in this paper, the notion of non-Hermitian dispersive hydrodynamics and its associated non-Hermitian Riemann problems are introduced. Starting from the defocusing (repulsive) NLS equation in the presence of generic smooth complex external potentials, a new set of hydrodynamic-like equations are obtained. They differ from their classical counterparts (without an external potential), by the presence of additional source terms that alter the density and momentum equations. When restricted to a class of Wadati-type complex potentials, this new non-Hermitian hydrodynamic system admits constant intensity/density solutions. This in turn, allows one to formulate an exact centered (or non-centered) Riemann problem involving a step-like initial condition that connects two exact constant density states. A broad class of non-Hermitian potentials that lead to modulationally stable constant intensity states are identified. These results are subsequently used to numerically solve the associated non-Hermitian Riemann problem for various initial conditions. Due to the lack of translation symmetry, the resulting long-time dynamics show a strong dependence on the location of the step relative to the gain-loss distribution. This is in sharp contrast to the classical NLS Riemann problem (in the absence of potential), where the dynamics are generally independent of the step location. This fact leads to {a diverse array of} wave pattern dynamics that are otherwise absent. In particular, various novel gain-loss generated near-field features are observed, which in turn drive the optical flows in the far-field. {These far-field non-Hermitian counter-flows could be comprised of various rich nonlinear wave phenomena, including DSW-DSW, DSW-rarefaction, and soliton-DSW interactions. A manuscript containing the results has been submitted to Nonlinearity \\\\cite{chandramouli2023nonHermitian}.} \\\\end{itemize}
Author: Alan Jeffrey
Publisher:
ISBN:
Category : Magnetohydrodynamics
Languages : en
Pages : 388
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Author:
Publisher: Elsevier
ISBN: 0080957803
Category : Mathematics
Languages : en
Pages : 381
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Book Description
In this book, we study theoretical and practical aspects of computing methods for mathematical modelling of nonlinear systems. A number of computing techniques are considered, such as methods of operator approximation with any given accuracy; operator interpolation techniques including a non-Lagrange interpolation; methods of system representation subject to constraints associated with concepts of causality, memory and stationarity; methods of system representation with an accuracy that is the best within a given class of models; methods of covariance matrix estimation;methods for low-rank matrix approximations; hybrid methods based on a combination of iterative procedures and best operator approximation; andmethods for information compression and filtering under condition that a filter model should satisfy restrictions associated with causality and different types of memory.As a result, the book represents a blend of new methods in general computational analysis,and specific, but also generic, techniques for study of systems theory ant its particularbranches, such as optimal filtering and information compression. - Best operator approximation,- Non-Lagrange interpolation,- Generic Karhunen-Loeve transform- Generalised low-rank matrix approximation- Optimal data compression- Optimal nonlinear filtering
Author: Jüri Engelbrecht
Publisher: Springer Science & Business Media
ISBN: 3642747892
Category : Science
Languages : en
Pages : 284
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Book Description
TIlis volume contains the contributions to the Euromech Colloquium No. 241 on Nonlinear Waves in Active Media at the Institute of Cybernetics of the Estonian Academy of Sciences, Tallinn, Estonia, USSR, September 27-30, 1988. The Co-chairmen of the Euromech Colloquium felt that it would be a good service to the community to publish these proceedings. First, the topic itself dealing with various wave processes with energy influx is extremely interesting and attracted a much larger number of participants than usual - a clear sign of its importance to the scientific community. Second, Euromech No. 241 was actually the first Euromech Colloquium held in the Soviet Union and could thus be viewed as a milestone in the extending scientific contacts between East and West. At the colloquium 50 researchers working in very different branches of sci ence met to lecture on their results and to discuss problems of common interest. An introductory paper by I. Engelbrecht presents the common motivation and background of the topics covered. Altogether 36 speakers presented their lectures, of which 30 are gathered here. The remaining six papers which will appear elsewhere are listed on page X. In addition, three contributions by authors who could not attend the colloquium are included. The two lectures given by A.S. Mikhailov, V.S. Davydov and V.S. Zykov are here published as one long paper.
Author: Francesco Romeo
Publisher: Springer Science & Business Media
ISBN: 3709113091
Category : Technology & Engineering
Languages : en
Pages : 332
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Book Description
Waves and defect modes in structures media.- Piezoelectric superlattices and shunted periodic arrays as tunable periodic structures and metamaterials.- Topology optimization.- Map-based approaches for periodic structures.- Methodologies for nonlinear periodic media. The contributions in this volume present both the theoretical background and an overview of the state-of-the art in wave propagation in linear and nonlinear periodic media in a consistent format. They combine the material issued from a variety of engineering applications, spanning a wide range of length scale, characterized by structures and materials, both man-made and naturally occurring, featuring geometry, micro-structural and/or materials properties that vary periodically in space, including periodically stiffened plates, shells and beam-like as well as bladed disc assemblies, phononic metamaterials, photonic crystals and ordered granular media. Along with linear models and applications, analytical methodologies for analyzing and exploiting complex dynamical phenomena arising in nonlinear periodic systems are also presented.
Author: A.G. Kulikovskii
Publisher: CRC Press
ISBN: 1000446417
Category : Mathematics
Languages : en
Pages : 252
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Book Description
Nonlinear Waves in Elastic Media explores the theoretical results of one-dimensional nonlinear waves, including shock waves, in elastic media. It is the first book to provide an in-depth and comprehensive presentation of the nonlinear wave theory while taking anisotropy effects into account. The theory is completely worked out and draws on 15 years of research by the authors, one of whom also wrote the 1965 classic Magnetohydrodynamics. Nonlinear Waves in Elastic Media emphasizes the behavior of quasitransverse waves and analyzes arbitrary discontinuity disintegration problems, illustrating that the solution can be non-unique - a surprising result. The solution is shown to be especially interesting when anisotropy and nonlinearity effects interact, even in small-amplitude waves. In addition, the text contains an independent mathematical chapter describing general methods to study hyperbolic systems expressing the conservation laws. The theoretical results described in Nonlinear Waves in Elastic Media allow, for the first time, discovery and interpretation of many new peculiarities inherent to the general problem of discontinuous solutions and so provide a valuable resource for advanced students and researchers involved with continuum mechanics and partial differential equations.
Author: Anatoli Torokhti
Publisher: Elsevier Science Limited
ISBN: 9780123749178
Category : Mathematics
Languages : en
Pages : 322
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Book Description
In this book, we study theoretical and practical aspects of computing methods for mathematical modelling of nonlinear systems. A number of computing techniques are considered, such as methods of operator approximation with any given accuracy; operator interpolation techniques including a non-Lagrange interpolation; methods of system representation subject to constraints associated with concepts of causality, memory and stationarity; methods of system representation with an accuracy that is the best within a given class of models; methods of covariance matrix estimation; methods for low-rank matrix approximations; hybrid methods based on a combination of iterative procedures and best operator approximation; and methods for information compression and filtering under condition that a filter model should satisfy restrictions associated with causality and different types of memory. As a result, the book represents a blend of new methods in general computational analysis, and specific, but also generic, techniques for study of systems theory ant its particular branches, such as optimal filtering and information compression. - Best operator approximation, - Non-Lagrange interpolation, - Generic Karhunen-Loeve transform - Generalised low-rank matrix approximation - Optimal data compression - Optimal nonlinear filtering
Author: Spencer P. Kuo
Publisher: World Scientific Publishing Company
ISBN: 9789811231636
Category : Electromagnetic waves
Languages : en
Pages : 0
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Book Description
Waves are essential phenomena in most scientific and engineering disciplines, such as electromagnetism and optics, and different mechanics including fluid, solid, structural, quantum, etc. They appear in linear and nonlinear systems. Some can be observed directly and others are not. The features of the waves are usually described by solutions to either linear or nonlinear partial differential equations, which are fundamental to the students and researchers. Generic equations, describing wave and pulse propagation in linear and nonlinear systems, are introduced and analyzed as initial/boundary value problems. These systems cover the general properties of non-dispersive and dispersive, uniform and non-uniform, with/without dissipations. Methods of analyses are introduced and illustrated with analytical solutions. Wave-wave and wave-particle interactions ascribed to the nonlinearity of media (such as plasma) are discussed in the final chapter. This interdisciplinary textbook is essential reading for anyone in above mentioned disciplines. It was prepared to provide students with an understanding of waves and methods of solving wave propagation problems. The presentation is self-contained and should be read without difficulty by those who have adequate preparation in classic mechanics. The selection of topics and the focus given to each provide essential materials for a lecturer to cover the bases in a linear/nonlinear wave course. Book jacket.
Author: Brian R Seymour
Publisher: World Scientific
ISBN: 9813100354
Category : Technology & Engineering
Languages : en
Pages : 420
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Book Description
This unique book aims to treat a class of nonlinear waves that are reflected from the boundaries of media of finite extent. It involves both standing (unforced) waves and resonant oscillations due to external periodic forcing. The waves are both hyperbolic and dispersive. To achieve this aim, the book develops the necessary understanding of linear waves and the mathematical techniques of nonlinear waves before dealing with nonlinear waves in bounded media. The examples used come mainly from gas dynamics, water waves and viscoelastic waves.
Author: Olof Erik Hans Rydbeck
Publisher:
ISBN:
Category : Radio waves
Languages : en
Pages :
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