1. Trang chủ
  2. » Giáo Dục - Đào Tạo

Engineering Electromagnetics 6th Edition

597 583 0

Đang tải... (xem toàn văn)

Tài liệu hạn chế xem trước, để xem đầy đủ mời bạn chọn Tải xuống

THÔNG TIN TÀI LIỆU

Thông tin cơ bản

Định dạng
Số trang 597
Dung lượng 14,13 MB

Nội dung

The McGraw-Hill Companies Engineering Electromagnetics Sixth Edition William H. Hayt, Jr. . John A. Buck Textbook Table of Contents The Textbook Table of Contents is your starting point for accessing pages within the chapter. Once you’re at this location, you can easily move back and forth within specific chapters or just as easily jump from one chapter to another. Textbook Website The Textbook Website is the McGraw-Hill Higher Education website developed to accompany this textbook. Here you’ll find numerous text-specific learning tools and resources that expand upon the information you normally find in a printed textbook. McGraw-Hill Website The McGraw-Hill Website is your starting point for discovery of all the educational content and services offered by McGraw-Hill Higher Education. Copyright @ 2001 The McGraw Companies. All rights reserved. Any use is subject to the Terms of Use and Privacy Policy. McGraw-Hill Higher Education is one of the many fine businesses of The McGraw-Hill Companies. If you have a question or a suggestion about a specific book or product, please fill out our User Feedback Form accessible from the main menu or contact our customer service line at 1-800-262-4729. Help Feedback Interactive e-Text Interactive e-Text | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents ? ✎ ▲ ▲ ▲ Engineering Electromagnetics | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents McGraw-Hill Series in Electrical and Computer Engineering SENIOR CONSULTING EDITOR Stephen W. Director, University of Michigan, Ann Arbor Circuits and Systems Communications and Signal Processing Computer Engineering Control Theory and Robotics Electromagnetics Electronics and VLSI Circuits Introductory Power Antennas, Microwaves, and Radar Previous Consulting Editors Ronald N. Bracewell, Colin Cherry, James F. Gibbons, Willis W. Harman, Hubert Heffner, Edward W. Herold, John G. Linvill, Simon Ramo, Ronald A. Rohrer, Anthony E. Siegman, Charles Susskind, Frederick E. Terman, John G. Truxal, Ernst Weber, and John R. Whinnery | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents Engineering Electromagnetics SIXTH EDITION William H. Hayt, Jr. Late Emeritus Professor Purdue University John A. Buck Georgia Institute of Technology Boston Burr Ridge, IL Dubuque, IA Madison, WI New York San Francisco St. Louis Bangkok Bogotá Caracas Lisbon London Madrid Mexico City Milan New Delhi Seoul Singapore Sydney Taipei Toronto | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents BRIEF CONTENTS Preface xi Chapter 1 Vector Analysis 1 Chapter 2 Coulomb's Law and Electric Field Intensity 27 Chapter 3 Electric Flux Density, Gauss' Law, and Divergence 53 Chapter 4 Energy and Potential 83 Chapter 5 Conductors, Dielectrics, and Capacitance 119 Chapter 6 Experimental Mapping Methods 169 Chapter 7 Poisson's and Laplace's Equations 195 Chapter 8 The Steady Magnetic Field 224 Chapter 9 Magnetic Forces, Materials, and Inductance 274 Chapter 10 Time-Varying Fields and Maxwell's Equations 322 Chapter 11 The Uniform Plane Wave 348 Chapter 12 Plane Waves at Boundaries and in Dispersive Media 387 Chapter 13 Transmission Lines 435 Chapter 14 Waveguide and Antenna Fundamentals 484 Appendix A Vector Analysis 529 Appendix B Units 534 Appendix C Material Constants 540 Appendix D Origins of the Complex Permittivity 544 Appendix E Answers to Selected Problems à Index 551 à To find Appendix E, please visit the expanded book website: www.mhhe.com/engcs/electrical/haytbuck v | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents PREFACE Over the years, I have developed a familiarity with this book in its various editions, having learned from it, referred to it, and taught from it. The second edition was used in my first electromagnetics course as a junior during the early '70's. Its simple and easy-to-read style convinced me that this material could be learned, and it helped to confirm my latent belief at the time that my specialty would lie in this direction. Later, it was not surprising to see my own students coming to me with heavily-marked copies, asking for help on the drill problems, and taking a more active interest in the subject than I usually observed. So, when approached to be the new co-author, and asked what I would do to change the book, my initial feeling wasÐnothing. Further reflection brought to mind earlier wishes for more material on waves and transmission lines. As a result, Chapters 1 to 10 are original, while 11 to 14 have been revised, and contain new material. A conversation with Bill Hayt at the project's beginning promised the start of what I thought would be a good working relationship. The rapport was immediate. His declining health prevented his active participation, but we seemed to be in general agreement on the approach to a revision. Although I barely knew him, his death, occurring a short time later, deeply affected me in the sense that someone that I greatly respected was gone, along with the promise of a good friendship. My approach to the revision has been as if he were still here. In the front of my mind was the wish to write and incorporate the new material in a manner that he would have approved, and which would have been consistent with the original objectives and theme of the text. Much more could have been done, but at the risk of losing the book's identity and possibly its appeal. Before their deaths, Bill Hayt and Jack Kemmerly completed an entirely new set of drill problems and end-of-chapter problems for the existing material at that time, up to and including the transmission lines chapter. These have been incorporated, along with my own problems that pertain to the new topics. The other revisions are summarized as follows: The original chapter on plane waves has now become two. The first (Chapter 11) is concerned with the development of the uniform plane wave and the treatment wave propagation in various media. These include lossy materials, where propagation and loss are now modeled in a general way using the complex permittivity. Conductive media are presented as special cases, as are materials that exhibit electronic or molecular resonances. A new appendix provides background on resonant media. A new section on wave polarization is also included. Chapter 12 deals with wave reflection at single and multiple interfaces, and at oblique incidence angles. An additional section on dispersive media has been added, which introduces the concepts of group velo- city and group dispersion. The effect of pulse broadening arising from group dispersion is treated at an elementary level. Chapter 13 is essentially the old transmission lines chapter, but with a new section on transients. Chapter 14 is intended as an introduction to waveguides and antennas, in which the underlying xi | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents physical concepts are emphasized. The waveguide sections are all new, but the antennas treatment is that of the previous editions. The approach taken in the new material, as was true in the original work, is to emphasize physical understanding and problem-solving skills. I have also moved the work more in the direction of communications-oriented material, as this seemed a logical way in which the book could evolve, given the material that was already there. The perspective has been broadened by an expanded emphasis toward optics concepts and applications, which are presented along with the more traditional lower-frequency discussions. This again seemed to be a logical step, as the importance of optics and optical communications has increased significantly since the earlier editions were published. The theme of the text has not changed since the first edition of 1958. An inductive approach is used that is consistent with the historical development. In it, the experimental laws are presented as individual concepts that are later unified in Maxwell's equations. Apart from the first chapter on vector analysis, the mathematical tools are introduced in the text on an as-needed basis. Throughout every edition, as well as this one, the primary goal has been to enable students to learn independently. Numerous examples, drill problems (usually having multiple parts), and end-of-chapter problems are provided to facilitate this. Answers to the drill problems are given below each problem. Answers to selected end-of-chapter problems can be found on the internet at www.mhhe.com/engcs/electrical/haytbuck. A solutions manual is also available. The book contains more than enough material for a one-semester course. As is evident, statics concepts are emphasized and occur first in the presentation. In a course that places more emphasis on dynamics, the later chapters can be reached earlier by omitting some or all of the material in Chapters 6 and 7, as well as the later sections of Chapter 8. The transmission line treatment (Chapter 13) relies heavily on the plane wave development in Chapters 11 and 12. A more streamlined presentation of plane waves, leading to an earlier arrival at transmis- sion lines, can be accomplished by omitting sections 11.5, 12.5, and 12.6. Chapter 14 is intended as an ``advanced topics'' chapter, in which the development of waveguide and antenna concepts occurs through the application of the methods learned in earlier chapters, thus helping to solidify that knowledge. It may also serve as a bridge between the basic course and more advanced courses that follow it. I am deeply indebted to several people who provided much-needed feed- back and assistance on the work. Glenn S. Smith, Georgia Tech, reviewed parts of the manuscript and had many suggestions on the content and the philosophy of the revision. Several outside reviewers pointed out errors and had excellent suggestions for improving the presentation, most of which, within time limita- tions, were taken. These include Madeleine Andrawis, South Dakota State University, M. Yousif El-Ibiary, University of Oklahoma, Joel T. Johnson, Ohio State University, David Kelley, Pennsylvania State University, Sharad R. Laxpati, University of Illinois at Chicago, Masoud Mostafavi, San Jose State University, Vladimir A. Rakov, University of Florida, Hussain Al-Rizzo, Sultan xii PREFACE | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents Qaboos University, Juri Silmberg, Ryerson Polytechnic University and Robert M. Weikle II, University of Virginia. My editors at McGraw-Hill, Catherine Fields, Michelle Flomenhoft, and Betsy Jones, provided excellent expertise and supportÐparticularly Michelle, who was almost in daily contact, and provided immediate and knowledgeable answers to all questions and concerns. My see- mingly odd conception of the cover illustration was brought into reality through the graphics talents of Ms Diana Fouts at Georgia Tech. Finally, much is owed to my wife and daughters for putting up with a part-time husband and father for many a weekend. John A. Buck Atlanta, 2000 PREFACE xiii | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents CONTENTS Preface xi Chapter 1 Vector Analysis 1 1.1. Scalars and Vectors 2 1.2. Vector Algebra 3 1.3. The Cartesian Coordinate System 4 1.4. Vector Components and Unit Vectors 6 1.5. The Vector Field 9 1.6. The Dot Product 10 1.7. The Cross Product 13 1.8. Other Coordinate Systems: Circular Cylindrical Coordinates 15 1.9. The Spherical Coordinate System 20 Chapter 2 Coulomb's Law and Electric Field Intensity 27 2.1. The Experimental Law of Coulomb 28 2.2. Electric Field Intensity 31 2.3. Field Due to a Continuous Volume Charge Distribution 36 2.4. Field of a Line Charge 38 2.5. Field of a Sheet Charge 44 2.6. Streamlines and Sketches of Fields 46 Chapter 3 Electric Flux Density, Gauss' Law, and Divergence 53 3.1. Electric Flux Density 54 3.2. Gauss' Law 57 3.3. Applications of Gauss' Law: Some Symmetrical Charge Distributions 62 3.4. Application of Gauss' Law: Differential Volume Element 67 3.5. Divergence 70 3.6. Maxwell's First Equation (Electrostatics) 73 3.7. The Vector Operator r and the Divergence Theorem 74 Chapter 4 Energy and Potential 83 4.1. Energy and Potential in a Moving Point Charge in an Electric Field 84 4.2. The Line Integral 85 4.3. De®nition of Potential Difference and Potential 91 4.4. The Potential Field of a Point Charge 93 vii | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents 4.5. The Potential Field of a System of Charges: Conservative Property 95 4.6. Potential Gradient 99 4.7. The Dipole 106 4.8. Energy Density in the Electric Field 110 Chapter 5 Conductors, Dielectrics, and Capacitance 119 5.1. Current and Current Density 120 5.2. Continuity of Current 122 5.3. Metallic Conductors 124 5.4. Conductor Properties and Boundary Conditions 129 5.5. The Method of Images 134 5.6. Semiconductors 136 5.7. The Nature of Dielectric Materials 138 5.8. Boundary Conditions for Perfect Dielectric Materials 144 5.9. Capacitance 150 5.10. Several Capacitance Examples 154 5.11. Capacitance of a Two-Wire Line 157 Chapter 6 Experimental Mapping Methods 169 6.1. Curvilinear Squares 170 6.2. The Iteration Method 176 6.3. Current Analogies 183 6.4. Physical Models 186 Chapter 7 Poisson's and Laplace's Equations 195 7.1 Poisson's and Laplace's Equations 196 7.2. Uniqueness Theorem 198 7.3. Examples of the Solution of Laplace's Equation 200 7.4. Example of the Solution of Poisson's Equation 207 7.5. Product Solution of Laplace's Equation 211 Chapter 8 The Steady Magnetic Field 224 8.1. Biot-Savart Law 225 8.2. Ampere's Circuital Law 232 8.3. Curl 239 8.4. Stokes' Theorem 246 8.5. Magnetic Flux and Magnetic Flux Density 251 8.6. The Scalar and Vector Magnetic Potentials 254 8.7. Derivation of the Steady-Magnetic-Field Laws 261 viii CONTENTS | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents [...]... and spherical coordinate systems are discussed in chap 14, and vector calculus appears in chap 18 | e-Text Main Menu | Textbook Table of Contents | 23 ENGINEERING ELECTROMAGNETICS 4 Thomas, G B., Jr., and R L Finney: ``Calculus and Analytic Geometry,'' 6th ed., Addison-Wesley Publishing Company, Reading, Mass., 1984 Vector algebra and the three coordinate systems we use are discussed in chap 13 Other... attention, and practice The drill problems, first met at the end of Sec 1.4, should be considered an integral part of the text and should all be | v v 1 | e-Text Main Menu | Textbook Table of Contents | ENGINEERING ELECTROMAGNETICS worked They should not prove to be difficult if the material in the accompanying section of the text has been thoroughly understood It take a little longer to ``read'' the chapter... multiplied by scalars The magnitude of the vector changes, but its direction does not when the scalar is positive, although it reverses direc- | e-Text Main Menu | Textbook Table of Contents | 3 ENGINEERING ELECTROMAGNETICS FIGURE 1.1 Two vectors may be added graphically either by drawing both vectors from a common origin and completing the parallelogram or by beginning the second vector from the head... 2; 3† and Q…2; À2; 1† (c) The differential volume element in cartesian coordinates; dx, dy, and dz are, in general, independent differentials | e-Text Main Menu | Textbook Table of Contents | 5 ENGINEERING ELECTROMAGNETICS common intersection of three surfaces, the planes x ˆ constant, y ˆ constant, and z ˆ constant, the constants being the coordinate values of the point Fig 1.2b shows the points P... 1† is therefore RPQ ˆ rQ À rP ˆ …2 À 1†ax ‡ …À2 À 2†ay ‡ …1 À 3†az ˆ ax À 4ay À 2az | v v The vectors rP ; rQ , and RPQ are shown in Fig 1.3c | e-Text Main Menu | Textbook Table of Contents | 7 ENGINEERING ELECTROMAGNETICS This last vector does not extend outward from the origin, as did the vector r we initially considered However, we have already learned that vectors having the same magnitude and... the example given above is fairly simple and only a rough approximation to a physical situation, a more exact expression would be correspond- | e-Text Main Menu | Textbook Table of Contents | 9 ENGINEERING ELECTROMAGNETICS ingly more complex and difficult to interpret We shall come across many fields in our study of electricity and magnetism which are simpler than the velocity example, an example in... multiply the component (scalar) by a, as illustrated by Fig 1.4b For example, the component of B in the direction of ax is B Á ax ˆ Bx , and the | e-Text Main Menu | Textbook Table of Contents | 11 ENGINEERING ELECTROMAGNETICS FIGURE 1.4 (a) The scalar component of B in the direction of the unit vector a is B Á a (b) The vector component of B in the direction of the unit vector a is …B Á a†a: component... is applied to the unit | v v FIGURE 1.5 The direction of A  B is in the direction of advance of a right-handed screw as A is turned into B: | e-Text Main Menu | Textbook Table of Contents | 13 ENGINEERING ELECTROMAGNETICS vectors ax and ay , we find ax  ay ˆ az , for each vector has unit magnitude, the two vectors are perpendicular, and the rotation of ax into ay indicates the positive z direction... because everyone uses  for a different angle in spherical coordinates The angle  is common to both cylindrical and spherical coordinates See? | e-Text Main Menu | Textbook Table of Contents | 15 ENGINEERING ELECTROMAGNETICS another plane (z ˆ constant) This corresponds to the location of a point in a cartesian coordinate system by the intersection of three planes (x ˆ constant, y ˆ constant, and z ˆ... the cartesian variables x; y; z and the cylindrical coordinate variables ; ; z There is no change in the variable z between the two systems | e-Text Main Menu | Textbook Table of Contents | 17 ENGINEERING ELECTROMAGNETICS From the other viewpoint, we may express the cylindrical variables in terms of x; y, and z: p  ˆ x2 ‡ y2 … ! 0† y …11†  ˆ tanÀ1 x zˆz We shall consider the variable . The McGraw-Hill Companies Engineering Electromagnetics Sixth Edition William H. Hayt, Jr. . John A. Buck Textbook Table of Contents The Textbook. Menu Textbook Table of Contents ? ✎ ▲ ▲ ▲ Engineering Electromagnetics | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents McGraw-Hill Series in Electrical and Computer Engineering SENIOR CONSULTING. Weber, and John R. Whinnery | | | | ▲ ▲ e-Text Main Menu Textbook Table of Contents Engineering Electromagnetics SIXTH EDITION William H. Hayt, Jr. Late Emeritus Professor Purdue University John A.

Ngày đăng: 01/07/2015, 09:50

TỪ KHÓA LIÊN QUAN