Anna R. Ghazaryan (USA Miami Univeristy), Stephane Lafortune (USA College of Charleston), Vahagn Manukian (USA Miami University)
Introduction to Traveling Waves
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Anna R. Ghazaryan (USA Miami Univeristy), Stephane Lafortune (USA College of Charleston), Vahagn Manukian (USA Miami University)
Introduction to Traveling Waves
- Gebundenes Buch
This book focuses on traveling waves for undergraduate and masters level students. Traveling waves are not typically covered in the undergraduate curriculum, and topics related to traveling waves are usually only covered in research papers, except for a few texts designed for students.
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This book focuses on traveling waves for undergraduate and masters level students. Traveling waves are not typically covered in the undergraduate curriculum, and topics related to traveling waves are usually only covered in research papers, except for a few texts designed for students.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 160
- Erscheinungstermin: 14. November 2022
- Englisch
- Abmessung: 162mm x 241mm x 17mm
- Gewicht: 376g
- ISBN-13: 9780367707057
- ISBN-10: 0367707055
- Artikelnr.: 64625780
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 160
- Erscheinungstermin: 14. November 2022
- Englisch
- Abmessung: 162mm x 241mm x 17mm
- Gewicht: 376g
- ISBN-13: 9780367707057
- ISBN-10: 0367707055
- Artikelnr.: 64625780
Anna R. Ghazaryan is a Professor of Mathematics at Miami University, Oxford, OH. She received her Ph.D. in 2005 from the Ohio State University. She is an applied analyst with research interests in applied dynamical systems, more precisely, traveling waves and their stability. Stéphane Lafortune is Professor of Mathematics at the College of Charleston in South Carolina. He earned his Ph.D. in Physics from the Université de Montréal and Université Paris VII in 2000. He is an applied mathematician who works on nonlinear waves phenomena. More precisely, he is interested in the theory of integrable systems and in the problems of existence and stability of solutions to nonlinear partial differential equations. Vahagn Manukian is an Associate Professor of Mathematics at Miami University. He obtained a M.A. Degree Mathematics from SUNY at Buffalo and a Ph.D. in mathematics from the Ohio State University in 2005. Vahagn Manukian uses dynamical systems methods such as local and global bifurcation theory to analyze singularly perturbed nonlinear reaction diffusions systems that model natural phenomena.
1. Nonlinear Traveling Waves. 1.1. Traveling Waves. 1.2. Reaction-Diffusion
Equations. 1.3. Traveling Waves as Solutions of Reaction-Diffusion
Equations. 1.4. Planar Waves. 1.5. Examples of Reaction-Diffusion
Equations. 1.6. Other Partial Differential Equations that Support Waves.
2. Systems of Reaction-Diffusion Equations posed on Infinite Domains. 2.1.
Systems of Reaction-Diffusion Equations. 2.2. Examples of
Reaction-Diffusion Systems. 3. Existence of Fronts, Pulses, and Wavetrains.
3.1. Traveling Waves as Orbits in the Associated Dynamical Systems. 3.2.
Dynamical Systems Approach: Equilibrium Points. 3.3. Existence of Fronts in
Fisher-KPP Equation: Trapping Region Technique. 3.4. Existence of Fronts in
Solid Fuel Combustion Model. 3.5. Wavetrains. 4. Stability of Fronts and
Pulses. 4.1. Stability: Introduction. 4.2. A Heuristic Presentation of
Spectral Stability for Front and Pulse Traveling Wave Solutions. 4.3.
Location of the Point Spectrum. 4.4. Beyond Spectral Stability.
Equations. 1.3. Traveling Waves as Solutions of Reaction-Diffusion
Equations. 1.4. Planar Waves. 1.5. Examples of Reaction-Diffusion
Equations. 1.6. Other Partial Differential Equations that Support Waves.
2. Systems of Reaction-Diffusion Equations posed on Infinite Domains. 2.1.
Systems of Reaction-Diffusion Equations. 2.2. Examples of
Reaction-Diffusion Systems. 3. Existence of Fronts, Pulses, and Wavetrains.
3.1. Traveling Waves as Orbits in the Associated Dynamical Systems. 3.2.
Dynamical Systems Approach: Equilibrium Points. 3.3. Existence of Fronts in
Fisher-KPP Equation: Trapping Region Technique. 3.4. Existence of Fronts in
Solid Fuel Combustion Model. 3.5. Wavetrains. 4. Stability of Fronts and
Pulses. 4.1. Stability: Introduction. 4.2. A Heuristic Presentation of
Spectral Stability for Front and Pulse Traveling Wave Solutions. 4.3.
Location of the Point Spectrum. 4.4. Beyond Spectral Stability.
1. Nonlinear Traveling Waves. 1.1. Traveling Waves. 1.2. Reaction-Diffusion
Equations. 1.3. Traveling Waves as Solutions of Reaction-Diffusion
Equations. 1.4. Planar Waves. 1.5. Examples of Reaction-Diffusion
Equations. 1.6. Other Partial Differential Equations that Support Waves.
2. Systems of Reaction-Diffusion Equations posed on Infinite Domains. 2.1.
Systems of Reaction-Diffusion Equations. 2.2. Examples of
Reaction-Diffusion Systems. 3. Existence of Fronts, Pulses, and Wavetrains.
3.1. Traveling Waves as Orbits in the Associated Dynamical Systems. 3.2.
Dynamical Systems Approach: Equilibrium Points. 3.3. Existence of Fronts in
Fisher-KPP Equation: Trapping Region Technique. 3.4. Existence of Fronts in
Solid Fuel Combustion Model. 3.5. Wavetrains. 4. Stability of Fronts and
Pulses. 4.1. Stability: Introduction. 4.2. A Heuristic Presentation of
Spectral Stability for Front and Pulse Traveling Wave Solutions. 4.3.
Location of the Point Spectrum. 4.4. Beyond Spectral Stability.
Equations. 1.3. Traveling Waves as Solutions of Reaction-Diffusion
Equations. 1.4. Planar Waves. 1.5. Examples of Reaction-Diffusion
Equations. 1.6. Other Partial Differential Equations that Support Waves.
2. Systems of Reaction-Diffusion Equations posed on Infinite Domains. 2.1.
Systems of Reaction-Diffusion Equations. 2.2. Examples of
Reaction-Diffusion Systems. 3. Existence of Fronts, Pulses, and Wavetrains.
3.1. Traveling Waves as Orbits in the Associated Dynamical Systems. 3.2.
Dynamical Systems Approach: Equilibrium Points. 3.3. Existence of Fronts in
Fisher-KPP Equation: Trapping Region Technique. 3.4. Existence of Fronts in
Solid Fuel Combustion Model. 3.5. Wavetrains. 4. Stability of Fronts and
Pulses. 4.1. Stability: Introduction. 4.2. A Heuristic Presentation of
Spectral Stability for Front and Pulse Traveling Wave Solutions. 4.3.
Location of the Point Spectrum. 4.4. Beyond Spectral Stability.