## Electromagnetic Theory for Microwaves and OptoelectronicsA text on electromagnetic fields and waves. It is useful reference for researchers and engineers in the areas of microwaves and optoelectronics. It discusses the field analysis of electromagnetic waves confined in material boundaries, or so-called guided waves, and electromagnetic waves in the dispersive media and anisotropic media. |

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please let me know if this book can be downloaded free of cost.....i want a pdf copy..

### Contents

Contents | 1 |

General formulation of the contradirectional mode coupling in Chapter | 4 |

Dielectric Waveguides and Resonators | 6 |

Periodic Structures and the Coupling of Modes | 7 |

2 | 55 |

conducting Dielectric Boundary TravelingStanding | 80 |

TransmissionLine Theory and Network Theory for Electro | 117 |

TimeVarying BoundaryValue Problems | 179 |

341 | 551 |

382 | 557 |

406 | 563 |

454 | 569 |

Gaussian Beams | 577 |

Scalar Diffraction Theory | 621 |

A SI Units and Gaussian Units | 673 |

Bessel Functions | 683 |

Metallic Waveguides and Resonant Cavities | 235 |

7 | 345 |

Electromagnetic Waves in Dispersive Media and Anisotropic | 475 |

Media | 513 |

319 | 545 |

E Matrices and Tensors | 689 |

696 | |

704 | |

### Other editions - View all

Electromagnetic Theory for Microwaves and Optoelectronics Kequian Zhang,Dejie Li Limited preview - 2007 |

Electromagnetic Theory for Microwaves and Optoelectronics Kequian Zhang,Dejie Li Limited preview - 2013 |

### Common terms and phrases

admittance amplitude angle angular wave number anisotropic media attenuation becomes Bessel functions boundary conditions cavity characteristic impedance complex coordinate system current density cutoff frequency denotes dielectric waveguide eigenfunctions eigenvalue equation electric and magnetic electric field expressions ﬁeld components field vector Figure given guided modes Helmholtz equations Hertz vector impedance transducer integral longitudinal lossless magnetic field Maxwell’s equations medium metallic waveguide normalized open-circuit orthogonal parameters perfect conductor permittivity perturbation phase velocity plane wave polarized wave port power flow Poynting vector problem ratio reciprocal rectangular waveguide reflected wave reflection coefficient refracted region resonant short-circuit surface shown in Fig sin2 sinusoidal solution source-free spherical standing wave Substituting symmetrical tangential component theorem TM modes transmission line transverse traveling wave two-port network uniform plane wave vector function voltage wave equations wave impedance wave propagating wave TM wavelength zero µϵ