Book contents
- Frontmatter
- Dedication
- Contents
- Preface to the second edition
- Preface to the first edition
- Acknowledgements
- To the reader
- List of notation
- 1 An overview of computational electromagnetics for RF and microwave applications
- 2 The finite difference time domain method: a one-dimensional introduction
- 3 The finite difference time domain method in two and three dimensions
- 4 A one-dimensional introduction to the method of moments: modelling thin wires and infinite cylinders
- 5 The application of the FEKO and NEC-2 codes to thin-wire antenna modelling
- 6 The method of moments for surface modelling
- 7 The method of moments and stratified media: theory
- 8 The method of moments and stratified media: practical applications of a commercial code
- 9 A one-dimensional introduction to the finite element method
- 10 The finite element method in two dimensions: scalar and vector elements
- 11 The finite element method in three dimensions
- 12 A selection of more advanced topics in full-wave computational electromagnetics
- Appendix A The Whitney element
- Appendix B The Newmark-β time-stepping algorithm References
- Appendix C On the convergence of the MoM Reference
- Appendix D Useful formulas for simplex coordinates
- Appendix E Web resources
- Appendix F MATLAB files supporting this text
- Index
Appendix F - MATLAB files supporting this text
Published online by Cambridge University Press: 05 July 2014
- Frontmatter
- Dedication
- Contents
- Preface to the second edition
- Preface to the first edition
- Acknowledgements
- To the reader
- List of notation
- 1 An overview of computational electromagnetics for RF and microwave applications
- 2 The finite difference time domain method: a one-dimensional introduction
- 3 The finite difference time domain method in two and three dimensions
- 4 A one-dimensional introduction to the method of moments: modelling thin wires and infinite cylinders
- 5 The application of the FEKO and NEC-2 codes to thin-wire antenna modelling
- 6 The method of moments for surface modelling
- 7 The method of moments and stratified media: theory
- 8 The method of moments and stratified media: practical applications of a commercial code
- 9 A one-dimensional introduction to the finite element method
- 10 The finite element method in two dimensions: scalar and vector elements
- 11 The finite element method in three dimensions
- 12 A selection of more advanced topics in full-wave computational electromagnetics
- Appendix A The Whitney element
- Appendix B The Newmark-β time-stepping algorithm References
- Appendix C On the convergence of the MoM Reference
- Appendix D Useful formulas for simplex coordinates
- Appendix E Web resources
- Appendix F MATLAB files supporting this text
- Index
Summary
A substantial number of Matlab files are available on the publisher's website www.cambridge.org/Davidson, supporting the theoretical material in this book. This appendix briefly describes the functionality of each main script. (Most have a number of functions associated with them.)
FDTD codes
fdtd_1D_demo This implements the 1D FDTD theory described in Section 2.4, for a transmission line with a sinusoidal excitation.
fdtd_1D_WB_demo This implements the 1D FDTD theory described in Section 2.5, for a transmission line with a wideband excitation.
fdtd_2D_demo This implements the 2D FDTD theory described in Section 3.2, for TE scattering from a PEC cylinder.
fdtd_2D_pml_demo This implements the PML described in Section 3.3.
fdtd_3D_demo This implements the 3D FDTD theory described in Section 3.4, for eigenanalysis of a PEC cavity.
MoM codes
static_mom This implements the 1D MOM theory described in Section 4.2, for a charged thin wire.
thin_dipole This implements the 1D MOM theory described in Section 4.3, for radiation from a center-fed thin dipole.
MoM_2D_TM This implements the MOM theory described in Section 4.6, for TM scattering from a PEC cylinder.
MoM3D_demo This implements the MOM theory described in Section 6.3, for scattering from a flat plate using the mixed potential EFIE using RWG basis functions.
MoM_Som This computes the input impedance of a thin printed dipole using the Sommerfeld MPIE MOM formulation of Chapter 7.
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- Computational Electromagnetics for RF and Microwave Engineering , pp. 496 - 497Publisher: Cambridge University PressPrint publication year: 2010
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