Pythonic geodynamics: implementations for fast computing
Material type:
TextLanguage: English Series: Lecture notes in earth system sciencesPublication details: Switzerland: Springer, 2018. Description: xvi, 227p. pbkISBN: 9783319857251Subject(s): GEODYNAMICS | GEOGRAPHIC INFORMATION SYSTEM | PYTHON | PHYSICAL GEOGRAPHYDDC classification: 551.2:004.421 Summary: This book addresses students and young researchers who want to learn to use numerical modeling to solve problems in geodynamics. Intended as an easy-to-use and self-learning guide, readers only need a basic background in calculus to approach most of the material. The book difficulty increases very gradually, through four distinct parts. The first is an introduction to the Python techniques necessary to visualize and run vectorial calculations. The second is an overview with several examples on classical Mechanics with examples taken from standard introductory physics books. The third part is a detailed description of how to write Lagrangian, Eulerian and Particles in Cell codes for solving linear and non-linear continuum mechanics problems. Finally the last one address advanced techniques like tree-codes, Boundary Elements, and illustrates several applications to Geodynamics. The entire book is organized around numerous examples in Python, aiming at encouraging the reader to learn by experimenting and experiencing, not by theory.
| Item type | Current library | Call number | Status | Date due | Barcode |
|---|---|---|---|---|---|
Book
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NISER LIBRARY | 551.2:004.421 MOR-P (Browse shelf(Opens below)) | Available | 24718 | |
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Book
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NISER LIBRARY | 551.2:004.421 MOR-P (Browse shelf(Opens below)) | Available | 24135 |
Table of Contents:
1. Introduction to Scientific Python
1.1. Front Matter
1.2. Bird’s Eye View
1.3. Visualization
1.4. Fast Python: NumPy and Cython
2. Second Part: Mechanics
2.1. Front Matter
2.2. Mechanics I: Kinematics
2.3. Mechanics II: Newtonian Dynamics
2.4. Insights on the Physics of Stokes Flow
3. Lattice Methods
3.1. Front Matter
3.2. Lagrangian Transport
3.3. Operator Formulation
3.4. Laplacian Operator and Diffusion
3.5. Beyond Linearity
4. Advanced Techniques
4.1. Front Matter
4.2. Trees, Particles, and Boundaries
4.3. Applications to Geodynamics
4.4. The Future
This book addresses students and young researchers who want to learn to use numerical modeling to solve problems in geodynamics. Intended as an easy-to-use and self-learning guide, readers only need a basic background in calculus to approach most of the material. The book difficulty increases very gradually, through four distinct parts. The first is an introduction to the Python techniques necessary to visualize and run vectorial calculations. The second is an overview with several examples on classical Mechanics with examples taken from standard introductory physics books. The third part is a detailed description of how to write Lagrangian, Eulerian and Particles in Cell codes for solving linear and non-linear continuum mechanics problems. Finally the last one address advanced techniques like tree-codes, Boundary Elements, and illustrates several applications to Geodynamics. The entire book is organized around numerous examples in Python, aiming at encouraging the reader to learn by experimenting and experiencing, not by theory.
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