Multiple Time Scales
- 1st Edition - August 1, 1985
- Imprint: Academic Press
- Editors: Jeremiah U. Brackbill, Bruce I. Cohen
- Language: English
- Paperback ISBN:9 7 8 - 1 - 4 8 3 2 - 3 6 5 7 - 5
- eBook ISBN:9 7 8 - 1 - 4 8 3 2 - 5 7 5 6 - 3
Multiple Time Scales presents various numerical methods for solving multiple-time-scale problems. The selection first elaborates on considerations on solving problems with… Read more
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Request a sales quoteMultiple Time Scales presents various numerical methods for solving multiple-time-scale problems. The selection first elaborates on considerations on solving problems with multiple scales; problems with different time scales; and nonlinear normal-mode initialization of numerical weather prediction models. Discussions focus on analysis of observations, nonlinear analysis, systems of ordinary differential equations, and numerical methods for problems with multiple scales. The text then examines the diffusion-synthetic acceleration of transport iterations, with application to a radiation hydrodynamics problem and implicit methods in combustion and chemical kinetics modeling. The publication ponders on molecular dynamics and Monte Carlo simulations of rare events; direct implicit plasma simulation; orbit averaging and subcycling in particle simulation of plasmas; and hybrid and collisional implicit plasma simulation models. Topics include basic moment method, electron subcycling, gyroaveraged particle simulation, and the electromagnetic direct implicit method. The selection is a valuable reference for researchers interested in pursuing further research on the use of numerical methods in solving multiple-time-scale problems.
Contributors
Preface
1. Considerations on Solving Problems with Multiple Scales
I. Introduction
II. Examples of Problems with Multiple Scales
III. Numerical Methods for Multiple-Scale Problems
IV. Summary and Perspectives
References
2. Problems with Different Time Scales
I. Introduction
II. Systems of Ordinary Differential Equations
III. Numerical Methods for Ordinary Differential Equations
IV. Partial Differential Equations
V. Shallow Water Equations
VI. Atmospheric Motions
VII. Plasma Physics
References
3. Nonlinear Normal-Mode Initialization of Numerical Weather Prediction Models
I. Introduction
II. Normal-Mode Analysis
III. Nonlinear Analysis
IV. Analysis of Observations
V. Remaining Problems
References
4. The Diffusion-Synthetic Acceleration of Transport Iterations, with Application to a Radiation Hydrodynamics Problem
I. Introduction
II. Transport Iteration Methods
III. A Problem in Radiation Hydrodynamics
IV. Time-Dependent Example Calculations
References
5. Implicit Methods in Combustion and Chemical Kinetics Modeling
I. Introduction
II. Stiffness and Implicit Methods
III. The Method of Lines
IV. Adaptive Meshing
V. Solution of the Nonlinear Equations
References
6. Implicit Adaptive-Grid Radiation Hydrodynamics
I. Introduction
II. Physical Equations
III. Adaptive-Mesh Equations
IV. Numerical Equations
V. The Adaptive Mesh
VI. Numerical Techniques
VII. Ordinary Gas Dynamics: Shock Tubes
VIII. Radiation Hydrodynamics: A Supercritical Shock
IX. A "Hubert Program" for Nonlinear Radiation Hydrodynamics
References
7. Multiple Time-Scale Methods in Tokamak Magnetohydrodynamics
I. Introduction
II. Ideal Time-Scale MHD Simulations
III. Resistive Time-Scale MHD Simulations
IV. Discussion
References
8. Hybrid and Collisional Implicit Plasma Simulation Models
I. Introduction
II. Basic Moment Method
III. Collisional-Hybrid Extensions
IV. Applications
V. Conclusion
References
9. Simulation of Low-Frequency Electromagnetic Phenomena in Plasmas
I. Introduction
II. Implicit Plasma Simulation
III. Implicit Formulation of the Dynamic Equations
IV. The Algorithm for the Implicit Moment Method
V. Properties of the Implicit Moment Method
VI. Computational Examples
VII. Conclusions
References
10. Orbit Averaging and Subcycling in Particle Simulation of Plasmas
I. Introduction
II. Electron Subcycling
III. Orbit Averaging
IV. Discussion
References
11. Direct Implicit Plasma Simulation
I. Introduction
II. Direct Method with Electrostatic Fields
III. Gyroaveraged Particle Simulation
IV. Electromagnetic Direct Implicit Method
V. Concluding Remarks
References
12. Direct Methods for N-Body Simulations
I. Introduction
II. Basic Formulation
III. Ahmad-Cohen Scheme
IV. Comoving Coordinates
V. Planetary Perturbations and Collisions
VI. Two-Body Regularization
VII. Three-Body Regularization
VIII. Star-Cluster Simulations
References
13. Molecular Dynamics and Monte Carlo Simulation of Rare Events
I. Introduction
II. Activated Barrier Crossing Theory and Methodology
III. Some Methods for Accelerating Simulations
IV. Summary
References
Subject Index
- Edition: 1
- Published: August 1, 1985
- No. of pages (eBook): 456
- Imprint: Academic Press
- Language: English
- Paperback ISBN: 9781483236575
- eBook ISBN: 9781483257563
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