Metasurface Electromagnetics
The Cagniard-DeHoop time-domain approach
Published on 9. June 2022
Book
Hardback
442 pages
978-1-83953-613-7 (ISBN)
Description
The book is entirely dedicated to the exploration of time-domain electromagnetic fields in the presence of thin, high contrast sheets, with an emphasis on metasurfaces combining magnetic and dielectric properties.
Since the number of problems that are amenable to exact solutions in terms of analytic functions is limited, the book's analysis is not restricted to analytical methods only, attention is paid to the development of computational and approximate techniques too. All the solution methodologies presented in the book heavily rely on the Cagniard-DeHoop technique. Regrettably, perhaps because of its origins in seismology, this powerful mathematical tool is still not fully appreciated in the electromagnetics and antenna community. It is hoped that this book will demonstrate the truly broad applicability of the Cagniard-DeHoop technique to achieving both analytical and numerical time-domain solutions. The book is for advanced researchers in computational electromagnetics and those looking for new approaches to modelling of metasurfaces.
The book also includes a foreword from Professor Adrianus T. de Hoop, the originator of the Cagniard-DeHoop technique, who ingeniously simplified a joint transform initially put forward by the French geophysicist Cagniard.
Since the number of problems that are amenable to exact solutions in terms of analytic functions is limited, the book's analysis is not restricted to analytical methods only, attention is paid to the development of computational and approximate techniques too. All the solution methodologies presented in the book heavily rely on the Cagniard-DeHoop technique. Regrettably, perhaps because of its origins in seismology, this powerful mathematical tool is still not fully appreciated in the electromagnetics and antenna community. It is hoped that this book will demonstrate the truly broad applicability of the Cagniard-DeHoop technique to achieving both analytical and numerical time-domain solutions. The book is for advanced researchers in computational electromagnetics and those looking for new approaches to modelling of metasurfaces.
The book also includes a foreword from Professor Adrianus T. de Hoop, the originator of the Cagniard-DeHoop technique, who ingeniously simplified a joint transform initially put forward by the French geophysicist Cagniard.
More details
Series
Language
English
Place of publication
Stevenage
United Kingdom
Target group
College/higher education
Professional and scholarly
Product notice
sewn/stitched
Cloth over boards
Dimensions
Height: 239 mm
Width: 160 mm
Thickness: 25 mm
Weight
885 gr
ISBN-13
978-1-83953-613-7 (9781839536137)
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Classification
Person
Martin Stumpf is an associate professor of theoretical electrical engineering with the Department of Radioelectronics, Brno University of Technology, Czech Republic. His research interests include modeling of electromagnetic wave phenomena with an emphasis on electromagnetic compatibility and antenna engineering. He is a senior member of the IEEE and the IEEE Antennas and Propagation and Electromagnetic Compatibility Societies.
Content
Chapter 1: Introduction
Chapter 2: Cagniard-DeHoop technique
Chapter 3: Thin-sheet high-contrast saltus-type conditions
Chapter 4: Pulsed EM-field response of an infinite metasurface
Chapter 5: Pulsed EM-field surface phenomena on thin sheets
Chapter 6: Pulsed EM-field diffraction by semi-infinite sheets
Chapter 7: Pulsed EM-field scattering by narrow metastrips
Chapter 8: Pulsed EM-field scattering by bounded metasurfaces in a homogeneous embedding
Chapter 9: Pulsed EM-field scattering by bounded and narrow screens in a layered embedding
Chapter 10: Pulsed EM-field coupling between bounded and narrow conductive screens
Chapter 11: Pulsed EM-field coupling between bounded and narrow metasurfaces
Chapter 12: Pulsed EM-field scattering by 3-D bounded metasurfaces
Chapter 13: Pulsed EM-field scattering by apertures
Chapter 14: Pulsed EM plane-wave scattering by time-varying metasurfaces
Chapter 15: Pulsed EM response of transmission lines over a metasurface
Chapter 16: Miscellaneous applications
Appendix A: Diffracted-wave amplitude
Appendix B: Impeditivity array of a PEC screen
Appendix C: Plane-wave excitation array
Appendix D: Impeditivity array of a screen with conductive and dielectric properties
Appendix E: Admittivity array of a PMC screen
Appendix F: Modified impeditivity array
Appendix G: Interface impeditivity array
Appendix H: Slab impeditivity array
Appendix I: Modified admittivity array
Appendix J: Coupling array of noncoplanar metasurfaces
Appendix K: Impedance array of a 3-D screen with dielectric and conductive properties
Appendix L: Recursive convolution technique
Chapter 2: Cagniard-DeHoop technique
Chapter 3: Thin-sheet high-contrast saltus-type conditions
Chapter 4: Pulsed EM-field response of an infinite metasurface
Chapter 5: Pulsed EM-field surface phenomena on thin sheets
Chapter 6: Pulsed EM-field diffraction by semi-infinite sheets
Chapter 7: Pulsed EM-field scattering by narrow metastrips
Chapter 8: Pulsed EM-field scattering by bounded metasurfaces in a homogeneous embedding
Chapter 9: Pulsed EM-field scattering by bounded and narrow screens in a layered embedding
Chapter 10: Pulsed EM-field coupling between bounded and narrow conductive screens
Chapter 11: Pulsed EM-field coupling between bounded and narrow metasurfaces
Chapter 12: Pulsed EM-field scattering by 3-D bounded metasurfaces
Chapter 13: Pulsed EM-field scattering by apertures
Chapter 14: Pulsed EM plane-wave scattering by time-varying metasurfaces
Chapter 15: Pulsed EM response of transmission lines over a metasurface
Chapter 16: Miscellaneous applications
Appendix A: Diffracted-wave amplitude
Appendix B: Impeditivity array of a PEC screen
Appendix C: Plane-wave excitation array
Appendix D: Impeditivity array of a screen with conductive and dielectric properties
Appendix E: Admittivity array of a PMC screen
Appendix F: Modified impeditivity array
Appendix G: Interface impeditivity array
Appendix H: Slab impeditivity array
Appendix I: Modified admittivity array
Appendix J: Coupling array of noncoplanar metasurfaces
Appendix K: Impedance array of a 3-D screen with dielectric and conductive properties
Appendix L: Recursive convolution technique