Table of contents 1. Complex Numbers and Functions. Complex Numbers. The Complex Plane. Polar Form.
|Published (Last):||16 December 2010|
|PDF File Size:||12.40 Mb|
|ePub File Size:||14.37 Mb|
|Price:||Free* [*Free Regsitration Required]|
About this title This reader-friendly book presents traditional material using a modern approach that invites the use of technology. Abundant exercises, examples, and graphics make it a comprehensive and visually appealing resource. Chapter topics include complex numbers and functions, analytic functions, complex integration, complex series, residues: applications and theory, conformal mapping, partial differential equations: methods and applications, transform methods, and partial differential equations in polar and spherical coordinates.
For engineers and physicists in need of a quick reference tool. Asmar received his Ph. D in mathematics from the University of Washington in After spending two years on the faculty of California State University, Long Beach, he joined the University of Missouri, Columbia in , where he is currently Professor of Mathematics.
He is also the author or co-author of over forty research articles in the areas of harmonic analysis, Fourier series, and functional analysis. His research received support from the National Science Foundation U.
He has received several teaching awards from the University of Missouri, including the William T. The author can be contacted by e-mail at the following address: nakhle math. All rights reserved. Chapters are intended for a one-term introductory course on the theory and applications of complex functions.
Chapters are intended for a one-term introductory course op partial differential equations and boundary value problems, that incorporates basic tools from complex variables such as contour integrals, residues, and Laurent series. Topics from Chapters can be chosen to form a one-term introductory course on complex variables with applications to partial differential equations and boundary value problems. In outlining its contents, I will present some of these differences in four components of the book: The examples and exercises, the applications, the graphics, and the proofs.
The Proofs In writing this book, my goal was to reach out to all students with varying abilities to do mathematical proofs. For that reason, I have included complete proofs of most results so as to give the instructor the flexibility to choose the proofs that he or she wants to present to the class, while skipping others and referring the students to the book. While recognizing the importance of training students in proof writing, I have tried not to let this learning process hinder their ability to see and appreciate the applications behind the theory.
In this book, all the proofs are written in a style that is very flexible for classroom presentation. They are carefully arranged and illustrated in such a way that they are accessible to students at the undergraduate level.
Some proofs are very basic for example, those found in the early sections of each chapter ; others require a deeper understanding of calculus for example, use of differentiability in Section 2. The latter advanced proofs are found in optional sections, such as Sections 2. Typically, in my courses, I would cover some of each level of proofs.
Even the most advanced proofs found a place in my courses, as assigned group projects and classroom presentation by students. The Graphics Drawing from my teaching experience, I learned that even the most abstract notions can benefit from graphics; and so I did use graphics liberally in this book.
I inserted as many pictures in the book as I felt is necessary to clarify an argument, or a statement of a problem, or the result of an example.
As a result, this book contains over seven hundred figures. In the exercises, I found that a statement such as "Solve the Dirichlet problem in Figure X," when accompanied by Figure X, is a much more inviting statement than, say, trying to describe by words the Dirichlet problem.
Moreover, it requires from the student to think about the problem, from the applied perspective and to write down the mathematical equations that describe the problem. The figures are extremely useful in visualizing the applications that are at the heart of the matter: heat flow, isotherms, vibrations of strings and membranes.
Graphics are also extremely useful in visualizing more abstract concepts, such as the maximum modulus principle Figure 6, Section 3. The Applications I started writing this book with what is now Section 2. My goal was to show students the applications of complex analysis as quickly as possible. More importantly, I wanted students to realize the significance of the abstract notions from complex analysis before taking up their detailed study. As a result, the book is written in the style of Section 2.
Whenever possible, I tried to describe the methods in a sequence of steps that a student can follow systematically. For example, in Section 2. Then immediately after that I solve an interesting Dirichlet problem by following these steps.
I have used the same approach to other important applications throughout the book. The Examples and Exercises I have included far more examples than can be covered in one course. The examples are presented in full detail. As with the proofs, the objective is to give the instructor he option to choose the examples that are best suitable for classroom discussion, while at the same time giving students a variety of completely worked examples to assist them in doing the exercises.
The exercises vary in difficulty from the straightforward ones that call on the application of a formula to the more involved Project Problems. All of the problems have been tested in the classroom, and the harder ones come with detailed hints to make them accessible to all students. Some of the longer exercises can be used by individual students, or as group projects, or as further illustrations by the instructor. Many sections in the book contain far more exercises than one would typically assign in a course.
Several exercises present interesting formulas and noteworthy results that are not found in many comparable books and that are more tractable with the availability of computer systems. Hopefully, even the experienced instructor will enjoy them as new material. Exercises that require the use of the computer are preceded by a computer icon, such as the one in the margin. Typically these exercises ask the student to investigate problems using computer-generated graphics, and to generate numerical data that cannot be computed by hand with a reasonable effort.
Occasionally, the computer is used to compute transforms, verify difficult identities, and aid in algebraic manipulations. Based on my teaching experience, I am convinced that such exercises are a great aid in understanding even the most abstract notions that are covered in the course. Possible Course Outlines The following are possible outlines of courses based on this book. Basic undergraduate course in complex analysis Chapter 1.
Chapter 2 Section 2. Chapter 3 Sections 3. Chapter 4 Section 4. Omit the proofs in Section 4. Chapter 5 Sections 5. Chapter 6 Sections 6.
Depending on the background and need of the students, these sections can be covered at different speed. In a course with less emphasis on proofs, more applications from the optional Sections 3. A course in partial differential equations to follow the basic course on complex analysis, as outlined previously. Chapter 7 Section 7. Chapter 8 Section 8. Chapter 9: Sections 9. Chapter 10 Section Chapters 11 and Refer to Sections 6. A one-term course in complex analysis and partial differential equations Complex Analysis Part: Chapter 1 Chapter 2: Section 2.
Cover Section 2. Chapter 3: Sections 3. Section 3. Sections 3. Chapter 4: Section 4. Skip the proofs in Sections 4. Do Section 4. Chapter 5: Sections 5. Chapter Sections Depending on the background and need of the students, these sections can be covered of different speed. In a course with less emphasis on proofs, more applications from Chapters 9 and 10 can be presented. Basic graduate course in complex analysis Cover the same topics as the basic undergraduate course, with more emphasis on proofs.
In particular, I would cover Sections 2.
0130892394 - Applied Complex Analysis with Partial Differential Equations by Asmar, Nakhle H
Nakhle Asmar's Home Page
ISBN 13: 9780130892393
Applied Complex Analysis with Partial Differential Equations