Mathematical Physics
Applied Mathematics for Scientists and Engineers
2. Edition January 2006
XI, 678 Pages, Softcover
Textbook
Short Description
A comprehensive treatment on the mathematical methods used in physics and engineering. One of its distinguishing features is its focus on using tools commonly used by scientists and engineers to solve real-world problems rather than presenting mathematics for its own sake.
What sets this volume apart from other mathematics texts is its emphasis on mathematical tools commonly used by scientists and engineers to solve real-world problems. Using a unique approach, it covers intermediate and advanced material in a manner appropriate for undergraduate students. Based on author Bruce Kusse's course at the Department of Applied and Engineering Physics at Cornell University, Mathematical Physics begins with essentials such as vector and tensor algebra, curvilinear coordinate systems, complex variables, Fourier series, Fourier and Laplace transforms, differential and integral equations, and solutions to Laplace's equations. The book moves on to explain complex topics that often fall through the cracks in undergraduate programs, including the Dirac delta-function, multivalued complex functions using branch cuts, branch points and Riemann sheets, contravariant and covariant tensors, and an introduction to group theory. This expanded second edition contains a new appendix on the calculus of variation -- a valuable addition to the already superb collection of topics on offer.
This is an ideal text for upper-level undergraduates in physics, applied physics, physical chemistry, biophysics, and all areas of engineering. It allows physics professors to prepare students for a wide range of employment in science and engineering and makes an excellent reference for scientists and engineers in industry. Worked out examples appear throughout the book and exercises follow every chapter. Solutions to the odd-numbered exercises are available for lecturers at www.wiley-vch.de/textbooks/.
2. Differential and Integral Operations on Vector and Scalar Fields
3. Curvilinear Coordinate Systems
4. Introduction to Tensors
5. The Dirac Delta-Function
6. Introduction to Complex Variables
7. Fourier Series
8. Fourier Transforms
9. Laplace Transforms
10. Differential Equations
11. Solutions to Laplace's Equation
12. Integral Equations
13. Advanced Topics in Complex Analysis
14. Tensors in Non-Orthogonal Coordinate Systems
15. Introduction to Group Theory
A. The Levi-Civita Identitiy
B. The Curvilinear Curl
C. The Double Integral Identity
D. Green's Function Solutions
E. Pseudovectors and the Mirror Test
F. Christoffel Symbols and Covariant Derivatives
NEW APPENDIX: The Calculus of Variation
Australian PHYSICS
Erik Westwig is a software engineer with Palisade Corporation, New Jersey. He holds an MS in applied physics from Cornell University.