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Computational problems for physics : with guided solutions using Python
- Author / Creator
- Available as
- Online
- Summary
-
"Our future scientists and professionals must be conversant in computational techniques. In order to facilitate integration of computer methods into existing physics courses, this textbook offers a...
"Our future scientists and professionals must be conversant in computational techniques. In order to facilitate integration of computer methods into existing physics courses, this textbook offers a large number of worked examples and problems with fully guided solutions in Python as well as other languages (Mathematica, Java, C, Fortran, and Maple). Its also intended as a self-study guide for learning how to use computer methods in physics. The authors include an introductory chapter on numerical tools and indication of computational and physics difficulty level for each problem. Readers also benefit from the following features: Detailed explanations and solutions in various coding languages. Problems are ranked based on computational and physics difficulty. Basics of numerical methods covered in an introductory chapter. Programming guidance via flowcharts and pseudocode.Rubin Landau is a Distinguished Professor Emeritus in the Department of Physics at Oregon State University in Corvallis and a Fellow of the American Physical Society (Division of Computational Physics).Manuel Jose Paez-Mejia is a Professor of Physics at Universidad de Antioquia in Medellín, Colombia."--Provided by publisher.
Details
- Creator
- Rubin H. Landau, Manuel José Páez
- Format
- Books
- Language
- English
- Contributors
- Publication
-
- First edition
- Boca Raton, FL : CRC Press, 2018
- ©2018
- Physical Details
-
- 1 online resource (xx, 411 pages) : illustrations
- ISBNs
- 9781315202099, 1315202093, 9781138705913, 9781138705418
- OCLC
- on1033538429
- Includes bibliographical references and index.
- Cover; Half Title; Title; Copyright; Contents; Acknowledgments; Series Preface; Preface; About the Authors; Web Materials; Chapter 1 Computational Basics for Physics; 1.1 Chapter Overview; 1.2 The Python Ecosystem; 1.2.1 Python Visualization Tools; 1.2.2 Python Matrix Tools; 1.2.3 Python Algebraic Tools; 1.3 Dealing with Floating Point Numbers; 1.3.1 Uncertainties in Computed Numbers; 1.4 Numerical Derivatives; 1.5 Numerical Integration; 1.5.1 Gaussian Quadrature; 1.5.2 Monte Carlo (Mean Value) Integration; 1.6 Random Number Generation; 1.6.1 Tests of Random Generators
- 1.6.2 Central Limit Theorem1.7 Ordinary Differential Equations Algorithms; 1.7.1 Euler & Runge-Kutta Rules; 1.8 Partial Differential Equations Algorithms; 1.9 Code Listings; Chapter 2 Data Analytics for Physics; 2.1 Chapter Overview; 2.2 Root Finding; 2.3 Least-Squares Fitting; 2.3.1 Linear Least-Square Fitting; 2.4 Discrete Fourier Transforms (DFT; 2.5 Fast Fourier Transforms (FFT; 2.6 Noise Reduction; 2.6.1 Noise Reduction via Autocorrelation Function; 2.6.2 Noise Reduction via Digital Filters; 2.7 Spectral Analysis of Nonstationary Signals; 2.7.1 Short-Time Fourier Transforms
- 2.7.2 Wavelet Analysis2.7.3 Discrete Wavelet Transforms, Multi-Resolution Analysis; 2.8 Principal Components Analysis (PCA; 2.9 Fractal Dimension Determination; 2.10 Code Listings; Chapter 3 Classical & Nonlinear Dynamics; 3.1 Chapter Overview; 3.2 Oscillators; 3.2.1 First a Linear Oscillator; 3.2.2 Nonlinear Oscillators; 3.2.3 Assessing Precision via Energy Conservation; 3.2.4 Models of Friction; 3.2.5 Linear & Nonlinear Resonances; 3.2.6 Famous Nonlinear Oscillators; 3.2.7 Solution via Symbolic Computing; 3.3 Realistic Pendula; 3.3.1 Elliptic Integrals; 3.3.2 Period Algorithm
- 3.3.3 Phase Space Orbits3.3.4 Vibrating Pivot Pendulum; 3.4 Fourier Analysis of Oscillations; 3.4.1 Pendulum Bifurcations; 3.4.2 Sonification; 3.5 The Double Pendulum; 3.6 Realistic Projectile Motion; 3.6.1 Trajectory of Thrown Baton; 3.7 Bound States; 3.8 Three-Body Problems: Neptune, Two Suns, Stars; 3.8.1 Two Fixed Suns with a Single Planet; 3.8.2 Hénon-Heiles Bound States; 3.9 Scattering; 3.9.1 Rutherford Scattering; 3.9.2 Mott Scattering; 3.9.3 Chaotic Scattering; 3.10 Billiards; 3.11 Lagrangian and Hamiltonian Dynamics; 3.11.1 Hamilton's Principle
- 3.11.2 Lagrangian & Hamiltonian Problems3.12 Weights Connected by Strings (Hard; 3.13 Code Listings; Chapter 4 Wave Equations & Fluid Dynamics; 4.1 Chapter Overview; 4.2 String Waves; 4.2.1 Extended Wave Equations; 4.2.2 Computational Normal Modes; 4.2.3 Masses on Vibrating String; 4.2.4 Wave Equation for Large Amplitudes; 4.3 Membrane Waves; 4.4 Shock Waves; 4.4.1 Advective Transport; 4.4.2 Burgers' Equation; 4.5 Solitary Waves (Solitons; 4.5.1 Including Dispersion, KdeV Solitons; 4.5.2 Pendulum Chain Solitons, Sine-Gordon Solitons; 4.6 Hydrodynamics; 4.6.1 Navier-Stokes Equation