Book description
This book is devoted to investigations of non-stationary electromagnetic processes. It offers a good opportunity to introduce the Volterra integral equation method more widely to the electromagnetic community. The explicit mathematical theory is combined with examples of its application in electromagnetic devices, optoelectronics, and photonics, where time-domain methods become a powerful tool for modeling. Particular consideration is given to electromagnetic transients in time-varying media and their potential applications.
Table of contents
- Front Cover
- Dedication
- Contents (1/2)
- Contents (2/2)
- Preface
- Acknowledgements
- Introduction (1/2)
- Introduction (2/2)
-
I. Basic Electromagnetic Effects in a Medium with Time-Varying Parameters and/or Moving Boundary
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (1/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (2/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (3/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (4/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (5/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (6/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (7/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (8/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (9/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (10/11)
- 1. Initial and Boundary Value Electromagnetic Problems in a Time-Varying Medium (11/11)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (1/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (2/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (3/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (4/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (5/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (6/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (7/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (8/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (9/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (10/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (11/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (12/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (13/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (14/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (15/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (16/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (17/18)
- 2. Transformation of an Electromagnetic Field in an Unbounded Medium with Time-Varying Parameters (18/18)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (1/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (2/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (3/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (4/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (5/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (6/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (7/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (8/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (9/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (10/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (11/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (12/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (13/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (14/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (15/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (16/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (17/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (18/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (19/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (20/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (21/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (22/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (23/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (24/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (25/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (26/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (27/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (28/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (29/30)
- 3. Influence of Medium Plane Boundaries on Electromagnetic Transients (30/30)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (1/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (2/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (3/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (4/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (5/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (6/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (7/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (8/9)
- 4. Non-Stationary Behaviour of Electromagnetic Waves Caused by the Movement of a Medium Boundary (9/9)
-
II. Electromagnetic Transients in Time-Varying Waveguides and Resonators
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (1/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (2/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (3/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (4/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (5/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (6/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (7/8)
- 5. An Electromagnetic Field in a Metallic Waveguide with a Moving Medium (8/8)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (1/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (2/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (3/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (4/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (5/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (6/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (7/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (8/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (9/10)
- 6. Interaction of an Electromagnetic Wave with a Plasma Bunch Moving in a Metallic Waveguide (10/10)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (1/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (2/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (3/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (4/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (5/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (6/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (7/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (8/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (9/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (10/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (11/12)
- 7. Non-Stationary Electromagnetic Processes in Time-Varying Dielectric Waveguides (12/12)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (1/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (2/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (3/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (4/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (5/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (6/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (7/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (8/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (9/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (10/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (11/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (12/13)
- 8. Electromagnetic Transients in Microcavities with Time-Varying Material Properties (13/13)
- Appendix A: Transformation of an Arbitrary Signal
- Appendix B: Taking into Account Solutions of a Homogeneous Equation in the Intermediate Evolution Stage (1/2)
- Appendix B: Taking into Account Solutions of a Homogeneous Equation in the Intermediate Evolution Stage (2/2)
- Appendix C: Lipshitz–Hankel Functions
- Appendix D: The Resolvent with Cylindrical Symmetry
- Appendix E: WGM Resonator with Transient Circular Inclusion (1/5)
- Appendix E: WGM Resonator with Transient Circular Inclusion (2/5)
- Appendix E: WGM Resonator with Transient Circular Inclusion (3/5)
- Appendix E: WGM Resonator with Transient Circular Inclusion (4/5)
- Appendix E: WGM Resonator with Transient Circular Inclusion (5/5)
Product information
- Title: Non-stationary Electromagnetics
- Author(s):
- Release date: September 2012
- Publisher(s): CRC Press
- ISBN: 9789814364249
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