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Electromagnetic Field Theory as one file: (PDF 1 of 3 - 3.9MB)(PDF 2 of 3 - 3.2MB)(PDF 3 of 3 - 3.3MB)
The style categories have been renumbered, reordered and recategorized. Please double-check the Guidelines to ensure the style number matches the name you are. EM NEU 2008 HAUPTK.Kursbuch (alum.) (German Edition) (German) Paperback – August 1, 2007 by Michaela Perlmann-Balme (Author), Susanne Schwalb (Author) 4.6 out of 5 stars 26 ratings.
Title: Em Neu 2008 Author: Perlmann-Balme, M., et al Description: New edition, to replace 'Em Neu'. Published Date: 2008 Publisher: Hueber.
ORTH-CHAMBAH, Jutta, Michaela PERLMANN-BALME a Susanne SCHWALB. Em neu 2008 Abschlusskurs: Deutsch als Fremdsprache: Niveaustufe C1.
April 1, 2008 may reveal fecal impaction, a palpable mass, or occult blood in the stool. Tenderness and fullness on the right side of the rectum suggest a retrocecal appendix.
Electromagnetic Field Theory Textbook Components
 Course schedule. TEXTBOOK CONTENTSFILES
Front-End Matter
Title page (PDF)
Dedication (PDF)
Preface (PDF)
Note to the student and instructor (PDF)
Table of contents, ix-xix (PDF)
Title page 2 (PDF)
Solutions to selected problems, pp. 699-710 (PDF)
Index, pp. 711-723 (PDF)
Useful equations and constants (PDF)
Chapter 1: Review of Vector Analysis, pp. 1-48 (PDF)
1.1 Coordinate systems, pp. 2-7
1.2 Vector Algebra, pp. 7-16
1.3 The gradient and the del operator, pp. 16-21
1.4 Flux and divergence, pp. 21-28
1.5 The Curl and Stokes' theorem, pp. 28-39
Problems, pp. 39-48
Sections 1.1-1.5 (PDF)
Problems (PDF)
Chapter 2: The Electric Field, pp. 49-134 (PDF - 8MB)
2.1 Electric charge, pp. 50-54
2.2 The Coulomb force law between stationary charges, pp. 54-59
2.3 Charge distributions, pp. 59-72
2.4 Gauss's law, pp. 72-84
2.5 The electric potential, pp. 84-93
2.6 The method of images with line charges and cylinders, pp. 93-103
2.7 The method of images with point charges and spheres, pp. 103-110
Problems, pp. 110-134
Sections 2.1-2.7 (PDF)
Problems (PDF - 2.7MB)
Chapter 3: Polarization and Conduction, pp. 135-256 (PDF - 1.9MB)
3.1 Polarization, pp. 136-152
3.2 Conduction, pp. 152-161
3.3 Field boundary conditions, 161-169
3.4 Resistance, pp. 169-173
3.5 Capacitance, pp. 173-181
3.6 Lossy media, pp. 181-197
3.7 Field-dependent space charge distributions, pp. 197-204
3.8 Energy stored in a dielectric medium, pp. 204-213
3.9 Fields and their forces, pp. 213-223
3.10 Electrostatic generators, pp. 223-231
Problems, pp. 231-256
Sections 3.1-3.10 (PDF - 1.4MB)
Problems (PDF)
Chapter 4: Electric Field Boundary Value Problems, pp. 257-312 (PDF)
4.1 The uniqueness theorem, pp. 258-259
4.2 Boundary value problems in Cartesian geometries, pp. 259-271
4.3 Separation of variables in cylindrical geometry, pp. 271-284
4.4 Product solutions in spherical geometry, pp. 284-297
4.5 A numerical method-successive relaxation, pp. 297-301
Problems, pp. 301-312
Sections 4.1-4.5 (PDF)
Problems (PDF)
Chapter 5: The Magnetic Field, pp. 313-392 (PDF - 1.2MB)
5.1 Forces on moving charges, pp. 314-322
5.2 Magnetic field due to currents, pp. 322-332
5.3 Divergence and curl of the magnetic field, pp. 332-336
5.4 The vector potential, pp. 336-343
5.5 Magnetization, pp. 343-359
5.6 Boundary conditions, pp. 359-361
5.7 Magnetic field boundary value problems, pp. 361-368
5.8 Magnetic fields and forces, pp. 368-375
Problems, pp. 375-392
Sections 5.1-5.8 (PDF)
Problems (PDF)
Chapter 6: Electromagnetic Induction, pp. 393-486 (PDF - 2.7MB)
6.1 Faraday's law of induction, pp. 395-405
6.2 Magnetic circuits, pp. 405-417
6.3 Faraday's law for moving media, pp. 417-435
6.4 Magnetic diffusion into an ohmic conductor, pp. 435-451
6.5 Energy stored in the magnetic field, pp. 451-460
6.6 The energy method for forces, pp. 460-465
Problems, pp. 465-486
Sections 6.1-6.6 (PDF - 1.1MB)
Problems (PDF)
Chapter 7: Electrodynamics-Fields and Waves, pp. 487-566 (PDF - 1.2MB)
7.1 Maxwell's equations, pp. 487-490
7.2 Conservation of energy, pp. 490-496
7.3 Transverse electromagnetic waves, pp. 496-505
7.4 Sinusoidal time variations, pp. 505-520
7.5 Normal incidence onto a perfect conductor, pp. 520-522
7.6 Normal incidence onto a dielectric, pp. 522-529
7.7 Uniform and nonuniform plane waves, pp. 529-534
7.8 Oblique incidence onto a perfect conductor, pp. 534-538
7.9 Oblique incidence onto a dielectric, pp. 538-544
7.10 Applications to optics, pp. 544-552
Problems, pp. 552-566
Sections 7.1-7.10 (PDF)
Problems (PDF)
Chapter 8: Guided Electromagnetic Waves, pp. 567-662 (PDF - 1.6MB)
8.1 The transmission line equations, pp. 568-579
8.2 Transmission line transient waves, pp. 579-595
8.3 Sinusoidal time variations, pp. 595-607
8.4 Arbitrary impedance terminations, pp. 607-620
8.5 Stub tuning, pp. 620-629
8.6 The rectangular waveguide, pp. 629-644
8.7 Dielectric waveguide, pp. 644-649
Problems, pp. 649-662
Sections 8.1-8.7 (PDF - 1.5MB)
Problems (PDF)
Chapter 9: Radiation, pp. 663-698 (PDF - 3.8MB)
9.1 The retarded potentials, pp. 664-667
9.2 Radiation from point dipoles, pp. 667-681
9.3 Point dipole arrays, pp. 681-687
9.4 Long dipole antennas, pp. 687-694
Problems, pp. 695-698
Sections 9.1-9.4 (PDF)
Problems (PDF)
Recommended CitationFor any use or distribution of this textbook, please cite as follows:
Em Neu 2008 Hauptkurs Kursbuch PdfMarkus Zahn, Electromagnetic Field Theory. (Massachusetts Institute of Technology: MIT OpenCourseWare). http://ocw.mit.edu (accessed MM DD, YYYY). License: Creative Commons Attribution-NonCommercial-Share Alike.

TEXTBOOK CONTENTS	FILES
Front-End Matter
Title page (PDF) Dedication (PDF) Preface (PDF) Note to the student and instructor (PDF) Table of contents, ix-xix (PDF) Title page 2 (PDF) Solutions to selected problems, pp. 699-710 (PDF) Index, pp. 711-723 (PDF) Useful equations and constants (PDF)
Chapter 1: Review of Vector Analysis, pp. 1-48 (PDF)
1.1 Coordinate systems, pp. 2-7 1.2 Vector Algebra, pp. 7-16 1.3 The gradient and the del operator, pp. 16-21 1.4 Flux and divergence, pp. 21-28 1.5 The Curl and Stokes' theorem, pp. 28-39 Problems, pp. 39-48	Sections 1.1-1.5 (PDF) Problems (PDF)
Chapter 2: The Electric Field, pp. 49-134 (PDF - 8MB)
2.1 Electric charge, pp. 50-54 2.2 The Coulomb force law between stationary charges, pp. 54-59 2.3 Charge distributions, pp. 59-72 2.4 Gauss's law, pp. 72-84 2.5 The electric potential, pp. 84-93 2.6 The method of images with line charges and cylinders, pp. 93-103 2.7 The method of images with point charges and spheres, pp. 103-110 Problems, pp. 110-134	Sections 2.1-2.7 (PDF) Problems (PDF - 2.7MB)
Chapter 3: Polarization and Conduction, pp. 135-256 (PDF - 1.9MB)
3.1 Polarization, pp. 136-152 3.2 Conduction, pp. 152-161 3.3 Field boundary conditions, 161-169 3.4 Resistance, pp. 169-173 3.5 Capacitance, pp. 173-181 3.6 Lossy media, pp. 181-197 3.7 Field-dependent space charge distributions, pp. 197-204 3.8 Energy stored in a dielectric medium, pp. 204-213 3.9 Fields and their forces, pp. 213-223 3.10 Electrostatic generators, pp. 223-231 Problems, pp. 231-256	Sections 3.1-3.10 (PDF - 1.4MB) Problems (PDF)
Chapter 4: Electric Field Boundary Value Problems, pp. 257-312 (PDF)
4.1 The uniqueness theorem, pp. 258-259 4.2 Boundary value problems in Cartesian geometries, pp. 259-271 4.3 Separation of variables in cylindrical geometry, pp. 271-284 4.4 Product solutions in spherical geometry, pp. 284-297 4.5 A numerical method-successive relaxation, pp. 297-301 Problems, pp. 301-312	Sections 4.1-4.5 (PDF) Problems (PDF)
Chapter 5: The Magnetic Field, pp. 313-392 (PDF - 1.2MB)
5.1 Forces on moving charges, pp. 314-322 5.2 Magnetic field due to currents, pp. 322-332 5.3 Divergence and curl of the magnetic field, pp. 332-336 5.4 The vector potential, pp. 336-343 5.5 Magnetization, pp. 343-359 5.6 Boundary conditions, pp. 359-361 5.7 Magnetic field boundary value problems, pp. 361-368 5.8 Magnetic fields and forces, pp. 368-375 Problems, pp. 375-392	Sections 5.1-5.8 (PDF) Problems (PDF)
Chapter 6: Electromagnetic Induction, pp. 393-486 (PDF - 2.7MB)
6.1 Faraday's law of induction, pp. 395-405 6.2 Magnetic circuits, pp. 405-417 6.3 Faraday's law for moving media, pp. 417-435 6.4 Magnetic diffusion into an ohmic conductor, pp. 435-451 6.5 Energy stored in the magnetic field, pp. 451-460 6.6 The energy method for forces, pp. 460-465 Problems, pp. 465-486	Sections 6.1-6.6 (PDF - 1.1MB) Problems (PDF)
Chapter 7: Electrodynamics-Fields and Waves, pp. 487-566 (PDF - 1.2MB)
7.1 Maxwell's equations, pp. 487-490 7.2 Conservation of energy, pp. 490-496 7.3 Transverse electromagnetic waves, pp. 496-505 7.4 Sinusoidal time variations, pp. 505-520 7.5 Normal incidence onto a perfect conductor, pp. 520-522 7.6 Normal incidence onto a dielectric, pp. 522-529 7.7 Uniform and nonuniform plane waves, pp. 529-534 7.8 Oblique incidence onto a perfect conductor, pp. 534-538 7.9 Oblique incidence onto a dielectric, pp. 538-544 7.10 Applications to optics, pp. 544-552 Problems, pp. 552-566	Sections 7.1-7.10 (PDF) Problems (PDF)
Chapter 8: Guided Electromagnetic Waves, pp. 567-662 (PDF - 1.6MB)
8.1 The transmission line equations, pp. 568-579 8.2 Transmission line transient waves, pp. 579-595 8.3 Sinusoidal time variations, pp. 595-607 8.4 Arbitrary impedance terminations, pp. 607-620 8.5 Stub tuning, pp. 620-629 8.6 The rectangular waveguide, pp. 629-644 8.7 Dielectric waveguide, pp. 644-649 Problems, pp. 649-662	Sections 8.1-8.7 (PDF - 1.5MB) Problems (PDF)
Chapter 9: Radiation, pp. 663-698 (PDF - 3.8MB)
9.1 The retarded potentials, pp. 664-667 9.2 Radiation from point dipoles, pp. 667-681 9.3 Point dipole arrays, pp. 681-687 9.4 Long dipole antennas, pp. 687-694 Problems, pp. 695-698	Sections 9.1-9.4 (PDF) Problems (PDF)

Welcome!This OCW supplemental resource provides material from outside the official MIT curriculum.
MIT OpenCourseWare is a free & open publication of material from thousands of MIT courses, covering the entire MIT curriculum.
No enrollment or registration. Freely browse and use OCW materials at your own pace. There's no signup, and no start or end dates.
Knowledge is your reward. Use OCW to guide your own life-long learning, or to teach others. We don't offer credit or certification for using OCW.
Made for sharing. Download files for later. Send to friends and colleagues. Modify, remix, and reuse (just remember to cite OCW as the source.)
Learn more at Get Started with MIT OpenCourseWare
Electromagnetic Field Theory as one file: (PDF 1 of 3 - 3.9MB)(PDF 2 of 3 - 3.2MB)(PDF 3 of 3 - 3.3MB)
Electromagnetic Field Theory Textbook Components

Welcome!This OCW supplemental resource provides material from outside the official MIT curriculum.
MIT OpenCourseWare is a free & open publication of material from thousands of MIT courses, covering the entire MIT curriculum.
No enrollment or registration. Freely browse and use OCW materials at your own pace. There's no signup, and no start or end dates.
Knowledge is your reward. Use OCW to guide your own life-long learning, or to teach others. We don't offer credit or certification for using OCW.
Made for sharing. Download files for later. Send to friends and colleagues. Modify, remix, and reuse (just remember to cite OCW as the source.)
Learn more at Get Started with MIT OpenCourseWare
Electromagnetic Field Theory as one file: (PDF 1 of 3 - 3.9MB)(PDF 2 of 3 - 3.2MB)(PDF 3 of 3 - 3.3MB)
Electromagnetic Field Theory Textbook Components
Em Abschlusskurs Neu 2008 Pdf Course schedule. TEXTBOOK CONTENTSFILES
Front-End Matter
Title page (PDF)
Dedication (PDF)
Preface (PDF)
Note to the student and instructor (PDF)
Table of contents, ix-xix (PDF)
Title page 2 (PDF)
Solutions to selected problems, pp. 699-710 (PDF)
Index, pp. 711-723 (PDF)
Useful equations and constants (PDF)
Chapter 1: Review of Vector Analysis, pp. 1-48 (PDF)
1.1 Coordinate systems, pp. 2-7
1.2 Vector Algebra, pp. 7-16
1.3 The gradient and the del operator, pp. 16-21
1.4 Flux and divergence, pp. 21-28
1.5 The Curl and Stokes' theorem, pp. 28-39
Problems, pp. 39-48
Sections 1.1-1.5 (PDF)
Problems (PDF)
Chapter 2: The Electric Field, pp. 49-134 (PDF - 8MB)
2.1 Electric charge, pp. 50-54
2.2 The Coulomb force law between stationary charges, pp. 54-59
2.3 Charge distributions, pp. 59-72
2.4 Gauss's law, pp. 72-84
2.5 The electric potential, pp. 84-93
2.6 The method of images with line charges and cylinders, pp. 93-103
2.7 The method of images with point charges and spheres, pp. 103-110
Problems, pp. 110-134
Sections 2.1-2.7 (PDF)
Problems (PDF - 2.7MB)
Chapter 3: Polarization and Conduction, pp. 135-256 (PDF - 1.9MB)
3.1 Polarization, pp. 136-152
3.2 Conduction, pp. 152-161
3.3 Field boundary conditions, 161-169
3.4 Resistance, pp. 169-173
3.5 Capacitance, pp. 173-181
3.6 Lossy media, pp. 181-197
3.7 Field-dependent space charge distributions, pp. 197-204
3.8 Energy stored in a dielectric medium, pp. 204-213
3.9 Fields and their forces, pp. 213-223
3.10 Electrostatic generators, pp. 223-231
Problems, pp. 231-256
Sections 3.1-3.10 (PDF - 1.4MB)
Problems (PDF)
Chapter 4: Electric Field Boundary Value Problems, pp. 257-312 (PDF)
4.1 The uniqueness theorem, pp. 258-259
4.2 Boundary value problems in Cartesian geometries, pp. 259-271
4.3 Separation of variables in cylindrical geometry, pp. 271-284
4.4 Product solutions in spherical geometry, pp. 284-297
4.5 A numerical method-successive relaxation, pp. 297-301
Problems, pp. 301-312
Sections 4.1-4.5 (PDF)
Problems (PDF)
Chapter 5: The Magnetic Field, pp. 313-392 (PDF - 1.2MB)
5.1 Forces on moving charges, pp. 314-322
5.2 Magnetic field due to currents, pp. 322-332
5.3 Divergence and curl of the magnetic field, pp. 332-336
5.4 The vector potential, pp. 336-343
5.5 Magnetization, pp. 343-359
5.6 Boundary conditions, pp. 359-361
5.7 Magnetic field boundary value problems, pp. 361-368
5.8 Magnetic fields and forces, pp. 368-375
Problems, pp. 375-392
Sections 5.1-5.8 (PDF)
Problems (PDF)
Chapter 6: Electromagnetic Induction, pp. 393-486 (PDF - 2.7MB)
6.1 Faraday's law of induction, pp. 395-405
6.2 Magnetic circuits, pp. 405-417
6.3 Faraday's law for moving media, pp. 417-435
6.4 Magnetic diffusion into an ohmic conductor, pp. 435-451
6.5 Energy stored in the magnetic field, pp. 451-460
6.6 The energy method for forces, pp. 460-465
Problems, pp. 465-486
Sections 6.1-6.6 (PDF - 1.1MB)
Problems (PDF)
Chapter 7: Electrodynamics-Fields and Waves, pp. 487-566 (PDF - 1.2MB)
7.1 Maxwell's equations, pp. 487-490
7.2 Conservation of energy, pp. 490-496
7.3 Transverse electromagnetic waves, pp. 496-505
7.4 Sinusoidal time variations, pp. 505-520
7.5 Normal incidence onto a perfect conductor, pp. 520-522
7.6 Normal incidence onto a dielectric, pp. 522-529
7.7 Uniform and nonuniform plane waves, pp. 529-534
7.8 Oblique incidence onto a perfect conductor, pp. 534-538
7.9 Oblique incidence onto a dielectric, pp. 538-544
7.10 Applications to optics, pp. 544-552
Problems, pp. 552-566
Sections 7.1-7.10 (PDF)
Problems (PDF)
Chapter 8: Guided Electromagnetic Waves, pp. 567-662 (PDF - 1.6MB)
8.1 The transmission line equations, pp. 568-579
8.2 Transmission line transient waves, pp. 579-595
8.3 Sinusoidal time variations, pp. 595-607
8.4 Arbitrary impedance terminations, pp. 607-620
8.5 Stub tuning, pp. 620-629
8.6 The rectangular waveguide, pp. 629-644
8.7 Dielectric waveguide, pp. 644-649
Problems, pp. 649-662
Sections 8.1-8.7 (PDF - 1.5MB)
Problems (PDF)
Chapter 9: Radiation, pp. 663-698 (PDF - 3.8MB)
9.1 The retarded potentials, pp. 664-667
9.2 Radiation from point dipoles, pp. 667-681
9.3 Point dipole arrays, pp. 681-687
9.4 Long dipole antennas, pp. 687-694
Problems, pp. 695-698
Sections 9.1-9.4 (PDF)
Problems (PDF)
Recommended CitationMicrosoft print to pdf missing in windows 7. For any use or distribution of this textbook, please cite as follows:
Markus Zahn, Electromagnetic Field Theory. (Massachusetts Institute of Technology: MIT OpenCourseWare). http://ocw.mit.edu (accessed MM DD, YYYY). License: Creative Commons Attribution-NonCommercial-Share Alike.
Em Neu 2008 Pdf FillableWelcome!This OCW supplemental resource provides material from outside the official MIT curriculum.
MIT OpenCourseWare is a free & open publication of material from thousands of MIT courses, covering the entire MIT curriculum.
No enrollment or registration. Freely browse and use OCW materials at your own pace. There's no signup, and no start or end dates.
Knowledge is your reward. Use OCW to guide your own life-long learning, or to teach others. We don't offer credit or certification for using OCW.
Made for sharing. Download files for later. Send to friends and colleagues. Modify, remix, and reuse (just remember to cite OCW as the source.)
Em Neu 2008 Pdf CombinerLearn more at Get Started with MIT OpenCourseWare