Computational Physics
Regular price
€96.99
A01=Steven E. Koonin
advanced physics curriculum
Author_Steven E. Koonin
Category=PBWH
Category=PH
Category=UMX
computational techniques for physical systems
Deflection Function
Dirichlet Boundary Conditions
eigenvalue problem solving
Eikonal Approximation
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Exact Ground State
Forward Recursion
H2 Molecule
Hartree Fock
Hartree Fock Equations
Lennard Jones Potential
matrix computation techniques
Metropolis Algorithm
Monte Carlo Evaluation
numerical simulation methods
Ordinary Differential Equation
Partial Wave
Project III
quantum mechanics modeling
Radial Wave Functions
Recursion Relation
Scattering Wave Function
Schroedinger Equation
Single Particle Wave Functions
statistical mechanics algorithms
Total Cross Section
Tri-diagonal Matrix
Trial Step
Trial Wave Function
Wave Function
White Dwarf
Product details
- ISBN 9780201386233
- Weight: 453g
- Dimensions: 152 x 229mm
- Publication Date: 01 Jul 1998
- Publisher: Taylor & Francis Inc
- Publication City/Country: US
- Product Form: Paperback
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Computational Physics is designed to provide direct experience in the computer modeling of physical systems. Its scope includes the essential numerical techniques needed to "do physics" on a computer. Each of these is developed heuristically in the text, with the aid of simple mathematical illustrations. However, the real value of the book is in the eight Examples and Projects, where the reader is guided in applying these techniques to substantial problems in classical, quantum, or statistical mechanics. These problems have been chosen to enrich the standard physics curriculum at the advanced undergraduate or beginning graduate level. The book will also be useful to physicists, engineers, and chemists interested in computer modeling and numerical techniques. Although the user-friendly and fully documented programs are written in FORTRAN, a casual familiarity with any other high-level language, such as BASIC, PASCAL, or C, is sufficient. The codes in BASIC and FORTRAN are available on the web at http://www.computationalphysics.info (Please follow the link at the bottom of the page). They are available in zip format, which can be expanded on UNIX, Window, and Mac systems with the proper software. The codes are suitable for use (with minor changes) on any machine with a FORTRAN-77 compatible compiler or BASIC compiler. The FORTRAN graphics codes are available as well. However, as they were originally written to run on the VAX, major modifications must be made to make them run on other machines.
Steven Koonin is Professor of Theoretical Physics and Provost at California Institute of Technology, where he has been a member of the faculty since 1975. He received his BS in physics from Caltech in 1972 and his Ph.D. in theoretical nuclear physics from MIT in 1975. Dr. Koonin's research interests include the theoretical description of nuclei and atoms. He is the author or co-author of numerous published papers and books, many involving large-scale numerical computation. Dawn Meredith is Associate Professor of Physics at the University of New Hampshire. She received her BA degree in Liberal Arts from St. John's College in Santa Fe, New Mexico and her Ph.D. degree in Physics from the California Institute of Technology. Dr. Meredith's research began in the study of nonlinear dynamics, and now focuses on physics education.
