Synopses & Reviews
Mathematica for Theoretical Physics: Electrodynamics, Quantum Mechanics, General Relativity, and Fractals This second edition of Baumann's Mathematica® in Theoretical Physics shows readers how to solve physical problems and deal with their underlying theoretical concepts while using Mathematica® to derive numeric and symbolic solutions. Each example and calculation can be evaluated by the reader, and the reader can change the example calculations and adopt the given code to related or similar problems. The second edition has been completely revised and expanded into two volumes: The first volume covers classical mechanics and nonlinear dynamics. Both topics are the basis of a regular mechanics course. The second volume covers electrodynamics, quantum mechanics, relativity, and fractals and fractional calculus. New examples have been added and the representation has been reworked to provide a more interactive problem-solving presentation. This book can be used as a textbook or as a reference work, by students and researchers alike. A brief glossary of terms and functions is contained in the appendices. The examples given in the text can also be interactively used and changed for the reader's purposes. The Author, Gerd Baumann, is affiliated with the Mathematical Physics Division of the University of Ulm, Germany, where he is professor. He is the author of Symmetry Analysis of Differential Equations with Mathematica®. Dr. Baumann has given numerous invited talks at universities and industry alike. He regularly hosts seminars and lectures on symbolic computing at the University of Ulm and at TECHNISCHE UNIVERSITÄT MÜNCHEN (TUM), Munich.
Review
From the reviews of the second edition: "The new edition contains a lot of additional material and new examples, and more emphasis is put on an interactive problem solving. In particular, advantage is taken of many special functions and frequently used operations which are available in Mathematica, in order to demonstrate how Mathematica can be used to replace lengthy 'by-hand' calculations and to give graphical support." (M. Plum, Zentralblatt MATH, Vol. 1095 (21), 2006)
Synopsis
This second edition of Baumann's Mathematica in Theoretical Physics shows readers how to solve physical problems and deal with their underlying theoretical concepts, while using Mathematica to derive numeric and analytic solutions. Each example and calculation can be evaluated through Mathematica, and the reader can change the example calculations and adopt the given code to related or similar problems. The second edition has been completely revised and is now expanded into two volumes. New examples have been added and the representation has been reworked to provide a more interactive problem-solving presentation. A glossary of terms and functions is contained in the appendices. This book will be an invaluable reference for students and researchers alike.
Synopsis
As physicists, mathematicians or engineers, we are all involved with mathematical calculations in our everyday work. Most of the laborious, complicated, and time-consuming calculations have to be done over and over again if we want to check the validity of our assumptions and derive new phenomena from changing models. Even in the age of computers, we often use paper and pencil to do our calculations. However, computer programs like Mathematica have revolutionized our working methods. Mathematica not only supports popular numerical calculations but also enables us to do exact analytical calculations by computer. Once we know the analytical representations of physical phenomena, we are able to use Mathematica to create graphical representations of these relations. Days of calculations by hand have shrunk to minutes by using Mathematica. Results can be verified within a few seconds, a task that took hours if not days in the past. The present text uses Mathematica as a tool to discuss and to solve examples from physics. The intention of this book is to demonstrate the usefulness of Mathematica in everyday applications. We will not give a complete description of its syntax but demonstrate by examples the use of its language. In particular, we show how this modern tool is used to solve classical problems. viii Preface This second edition of Mathematica in Theoretical Physics seeks to prevent the objectives and emphasis of the previous edition.
Synopsis
Class-tested textbook that shows readers how to solve physical problems and deal with their underlying theoretical concepts while using Mathematica® to derive numeric and symbolic solutions. Delivers dozens of fully interactive examples for learning and implementation, constants and formulae can readily be altered and adapted for the user's purposes. New edition offers enlarged two-volume format suitable to courses in mechanics and electrodynamics, while offering dozens of new examples and a more rewarding interactive learning environment.
About the Author
The Author, Gerd Baumann, is affiliated with the Mathematical Physics Division of the University of Ulm, Germany, where he is professor. He is the author of Symmetry Analysis of Differential Equations with Mathematica®. Dr. Baumann has given numerous invited talks at universities and industry alike. He regularly hosts seminars and lectures on symbolic computing at the University of Ulm and at TECHNISCHE UNIVERSITÄT MÜNCHEN (TUM), Munich.
Table of Contents
Preface - Electrodynamics: Introduction.- Potential and Electric Field of Discrete Charge Distributions.- Boundary Problem of Electrostatics.- Two Ions in the Penning Trap.- Exercises.- Packages and Programs - Quantum Mechanics: Introduction.- The Schrödinger Equation.- One Dimensional Potential.- The Harmonic Oscillator.- Anharmonic Oscillator.- Motion in the Central Force Field.- Second Virial Coefficient and Its Quantum Corrections.- Exercises.- Packages and Programs - General Relativity: Introduction.- The Orbits in General Relativity.- Light Bending in the Gravitational Field.- Einstein's Field Equations (Vacuum Case).- The Schwarzschild Solution.- The Reissner-Nordstrom Solution for a Charged Mass Point.- Exercises.- Packages and Programs - Fractals: Introduction.- Measuring a Borderline.- The Koch Curve.- Multi-Fractals.- The Renormalization Group.- Fractional Calculus.- Exercises.- Packages and Programs - Appendix - Index.