Table of contents http://www.loc.gov/catdir/toc/wiley041/2003065001.html
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Library | Materyal Türü | Barkod | Yer Numarası | Durum |
|---|---|---|---|---|
Searching... Pamukkale Merkez Kütüphanesi | Kitap | 0050080 | TK7876P69 2005 | Searching... Unknown |
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Focusing on the design of microwave circuits and components, this valuable reference offers professionals and students an introduction to the fundamental concepts necessary for real world design. The author successfully introduces Maxwell's equations, wave propagation, network analysis, and design principles as applied to modern microwave engineering. A considerable amount of material in this book is related to the design of specific microwave circuits and components, for both practical and motivational value. It also presents the analysis and logic behind these designs so that the reader can see and understand the process of applying the fundamental concepts to arrive at useful results. The derivations are well laid out and the majority of each chapter's formulas are displayed in a nice tabular format every few pages. This Third Edition offers greatly expanded coverage with new material on: Noise; Nonlinear effects; RF MEMs; transistor power amplifiers; FET mixers; oscillator phase noise; transistor oscillators and frequency multiplier.
Author Notes
David Pozar is a professor of electrical and computer engineering at the University of Massachusetts at Amherst, where he has worked since 1980. Pozar has written numerous books on the topic of microwave engineering such as Microwave Engineering (1997) and Antenna Design Using Personal Computers (1985).
Pozar attended the University of Akron, earning both a BS and an MS in Electrical Engineering. He received his Ph.D. in Electrical Engineering from The Ohio State University in 1980. He is active in the IEEE Association and has won several awards from them for outstanding contributions. He has also received an outstanding senior faculty award and a R.W.P. King Best Paper award, among others.
An active speaker at trade meetings worldwide, Pozar is also interested in fine woodworking and has created reproductions of antique furniture. He is married and has two children.
(Bowker Author Biography)
Table of Contents
| 1 Electromagnetic Theory |
| 1.1 Introduction to Microwave Engineering |
| Applications of Microwave Engineering |
| A Short History of Microwave Engineering |
| 1.2 Maxwell's Equations |
| 1.3 Fields in Media and Boundary Conditions |
| Fields at a General Material Interface 11 Fields at a Dielectric Interface |
| Fields at the Interface with a Perfect Conductor (Electric Wall) |
| The MagneticWall Boundary Condition |
| The Radiation Condition |
| 1.4 The Wave Equation and Basic Plane Wave Solutions |
| The Helmholtz Equation |
| Plane Waves in a Lossless Medium |
| Plane Waves in a General Lossy Medium |
| Plane Waves in a Good Conductor |
| 1.5 General Plane Wave Solutions |
| Circularly Polarized Plane Waves |
| 1.6 Energy and Power |
| Power Absorbed by a Good Conductor |
| 1.7 Plane Wave Reflection from a Media Interface |
| General Medium |
| Lossless Medium |
| Good Conductor |
| Perfect Conductor |
| The Surface Impedance Concept |
| 1.8 Oblique Incidence at a Dielectri c Interface |
| Parallel Polarization |
| Perpendicular Polarization |
| Total Reflection and Surface Waves |
| 1.9 Some Useful Theorems |
| The Reciprocity Theorem |
| Image Theory |
| 2 Transmission Line Theory |
| 2.1 The Lumped-Element Circuit Model for a Transmission Line |
| Wave Propagation on a Transmission Line |
| The Lossless Line |
| 2.2 Field Analysis of Transmission Lines |
| Transmission Line Parameters |
| The Telegrapher Equations Derived from Field Analysis of a Coaxial Line |
| Propagation Constant, Impedance, and Power Flow for the Lossless Coaxial Line |
| 2.3 The Terminated Lossless Transmission Line |
| Special Cases of Lossless Terminated Lines |
| 2.4 The Smith Chart |
| The Combined Impedance-Admittance Smith Chart |
| The Slotted Line |
| 2.5 The Quarter-Wave Transformer |
| The Impedance Viewpoint |
| The Multiple Reflection Viewpoint |
| 2.6 Generator and Load Mismatches |
| Load Matched to Line |
| Generator Matched to Loaded Line |
| Conjugate Matching |
| 2.7 Lossy Transmission Lines |
| The Low-Loss Line |
| The Distortionless Line |
| The Terminated Lossy Line |
| The Perturbation Method for Calculating Attenuation |
| The Wheeler Incremental Inductance Rule |
| 3 Transmission lines and waveguides |
| 3.1 General Solutions for TEM, TE, and TM Waves |
| TEM Waves |
| TE Waves |
| TM Waves |
| Attenuation Due to Dielectric Loss |
| 3.2 Parallel Plate Waveguide |
| TEM Modes |
| TM Modes |
| TE Modes |
| 3.3 RectangularWaveguide |
| TE Modes |
| TM Modes |
| TEm0 Modes of a Partially Loaded Waveguide |
| 3.4 Circular Waveguide |
| TE Modes |
| TM Modes |
| 3.5 Coaxial Line |
| TEM Modes |
| Higher Order Modes |
| 3.6 Surface Waves on a Grounded Dielectric Slab |
| TM Modes |
| TE Modes |
| 3.7 Stripline |
| Formulas for Propagation Constant, Characteristic Impedance, and Attenuation |
| An Approximate Electrostatic Solution |
| 3.8 Microstrip |
| Formulas for Effective Dielectric Constant, Characteristic Impedance, and Attenuation |
| An Approximate Electrostatic Solution |
| 3.9 The Transverse Resonance Technique |
| TE0n Modes of a Partially Loaded Rectangular Waveguide |
| 3.10 Wave Velocities and Dispersion |
| Group Velocity |
| 3.11 Summary of Transmission Lines and Waveguides |
| Other Types of Lines and Guides |
| 4 Microwave Network Analysis |
| 4.1 Impedance and Equivalent Voltages and Currents |
| Equivalent Voltages and Currents |
| The Concept of Impedance |
| Even and Odd Properties of Z(?) and _(?) |
| 4.2 Impedance and Admittance Matrices |
| Reciprocal Networks |
| Lossless Networks |
| 4.3 The Scattering Matrix |
| Reciprocal Networks and Lossless Networks |
| A Shift in Reference Planes |
| Generalized Scattering Parameters |
| 4.4 The Transmission (ABCD) Matrix |
| Relation to Impedance Matrix |
| Equivalent Circuits for Two-Port Networks |
| 4.5 Signal Flow Graphs |
| Decomposi |