| Preface |
| Acknowledgments |
| Introduction / 1: |
| Beginning of Wireless / 1.1: |
| Current Radio Spectrum / 1.2: |
| Conventions Used in This Text / 1.3: |
| Sections |
| Equations |
| Figures |
| Exercises |
| Symbols |
| Prefixes |
| Fonts |
| Vectors and Coordinates / 1.4: |
| General Constants and Useful Conversions / 1.5: |
| Review of AC Analysis and Network Simulation / 2: |
| Basic Circuit Elements / 2.1: |
| The Resistor |
| Ohm's Law |
| The Inductor |
| The Capacitor |
| Kirchhoff's Laws / 2.2: |
| Alternating Current (AC) Analysis / 2.3: |
| Ohm's Law in Complex Form |
| Voltage and Current Phasors / 2.4: |
| Impedance / 2.5: |
| Estimating Reactance |
| Addition of Series Impedances |
| Admittance / 2.6: |
| Admittance Definition |
| Addition of Parallel Admittances |
| The Product over the Sum |
| LLFPB Networks / 2.7: |
| Decibels, dBW, and dBm / 2.8: |
| Logarithms (Logs) |
| Multiplying by Adding Logs |
| Dividing by Subtracting Logs |
| Zero Powers |
| Bel Scale |
| Decibel Scale |
| Decibels--Relative Measures |
| Absolute Power Levels--dBm and dBW |
| Decibel Power Scales |
| Power Transfer / 2.9: |
| Calculating Power Transfer |
| Maximum Power Transfer |
| Specifying Loss / 2.10: |
| Insertion Loss |
| Transducer Loss |
| Loss Due to Series Impedance |
| Loss Due to Shunt Admittance |
| Loss in Terms of Scattering Parameters |
| Real RLC Models / 2.11: |
| Resistor with Parasitics |
| Inductor with Parasitics |
| Capacitor with Parasitics |
| Designing LC Elements / 2.12: |
| Lumped Coils |
| High [mu] Inductor Cores--the Hysteresis Curve |
| Estimating Wire Inductance |
| Parallel Plate Capacitors |
| Skin Effect / 2.13: |
| Network Simulation / 2.14: |
| LC Resonance and Matching Networks / 3: |
| LC Resonance / 3.1: |
| Series Circuit Quality Factors / 3.2: |
| Q of Inductors and Capacitors |
| Q[subscript E], External Q |
| Q[subscript L], Loaded Q |
| Parallel Circuit Quality Factors / 3.3: |
| Coupled Resonators / 3.4: |
| Direct Coupled Resonators |
| Lightly Coupled Resonators |
| Q Matching / 3.5: |
| Low to High Resistance |
| Broadbanding the Q Matching Method |
| High to Low Resistance |
| Distributed Circuit Design / 4: |
| Transmission Lines / 4.1: |
| Wavelength in a Dielectric / 4.2: |
| Pulses on Transmission Lines / 4.3: |
| Incident and Reflected Waves / 4.4: |
| Reflection Coefficient / 4.5: |
| Return Loss / 4.6: |
| Mismatch Loss / 4.7: |
| Mismatch Error / 4.8: |
| The Telegrapher Equations / 4.9: |
| Transmission Line Wave Equations / 4.10: |
| Wave Propagation / 4.11: |
| Phase and Group Velocities / 4.12: |
| Reflection Coefficient and Impedance / 4.13: |
| Impedance Transformation Equation / 4.14: |
| Impedance Matching with One Transmission Line / 4.15: |
| Fano's (and Bode's) Limit / 4.16: |
| Mismatched Loads / Type A: |
| Impedance Transformation Not Included / Type B: |
| The Smith Chart / 5: |
| Basis of the Smith Chart / 5.1: |
| Drawing the Smith Chart / 5.2: |
| Admittance on the Smith Chart / 5.3: |
| Tuning a Mismatched Load / 5.4: |
| Slotted Line Impedance Measurement / 5.5: |
| VSWR = r / 5.6: |
| Negative Resistance Smith Chart / 5.7: |
| Navigating the Smith Chart / 5.8: |
| Smith Chart Software / 5.9: |
| Estimating Bandwidth on the Smith Chart / 5.10: |
| Approximate Tuning May Be Better / 5.11: |
| Frequency Contours on the Smith Chart / 5.12: |
| Using the Smith Chart without Transmission Lines / 5.13: |
| Constant Q Circles / 5.14: |
| Transmission Line Lumped Circuit Equivalent / 5.15: |
| Matrix Analysis / 6: |
| Matrix Algebra / 6.1: |
| Z and Y Matrices / 6.2: |
| Reciprocity / 6.3: |
| The ABCD Matrix / 6.4: |
| The Scattering Matrix / 6.5: |
| The Transmission Matrix / 6.6: |
| Electromagnetic Fields and Waves / 7: |
| Vector Force Fields / 7.1: |
| E and H Fields / 7.2: |
| Electric Field E / 7.3: |
| Magnetic Flux Density / 7.4: |
| Vector Cross Product / 7.5: |
| Electrostatics and Gauss's Law / 7.6: |
| Vector Dot Product and Divergence / 7.7: |
| Static Potential Function and the Gradient / 7.8: |
| Divergence of the B Field / 7.9: |
| Ampere's Law / 7.10: |
| Vector Curl / 7.11: |
| Faraday's Law of Induction / 7.12: |
| Maxwell's Equations / 7.13: |
| Maxwell's Four Equations |
| Auxiliary Relations and Definitions |
| Visualizing Maxwell's Equations |
| Primary Vector Operations / 7.14: |
| The Laplacian / 7.15: |
| Vector and Scalar Identities / 7.16: |
| Free Charge within a Conductor / 7.17: |
| Conductor Internal Impedance / 7.18: |
| The Wave Equation / 7.20: |
| The Helmholtz Equations / 7.21: |
| Plane Propagating Waves / 7.22: |
| Poynting's Theorem / 7.23: |
| Wave Polarization / 7.24: |
| EH Fields on Transmission Lines / 7.25: |
| Waveguides / 7.26: |
| General Waveguide Solution |
| Waveguides Types |
| Rectangular Waveguide Field |
| Applying Boundary Conditions |
| Propagation Constants and Waveguide Modes |
| Characteristic Wave Impedance for Waveguides |
| TE and TM Mode Summary for Rectangular Waveguide |
| Fourier Series and Green's Functions / 7.27: |
| Fourier Series |
| Green's Functions |
| Higher Order Modes in Circuits / 7.28: |
| Vector Potential / 7.29: |
| Retarded Potentials / 7.30: |
| Potential Functions in the Sinusoidal Case / 7.31: |
| Antennas / 7.32: |
| Short Straight Wire Antenna |
| Radiation Resistance |
| Radiation Pattern |
| Half-Wavelength Dipole |
| Antenna Gain |
| Antenna Effective Area |
| Monopole Antenna |
| Aperture Antennas |
| Phased Arrays |
| Path Loss / 7.33: |
| Electromagnetic (EM) Simulation / 7.34: |
| Directional Couplers / 8: |
| Wavelength Comparable Dimensions / 8.1: |
| The Backward Wave Coupler / 8.2: |
| Even- and Odd-Mode Analysis / 8.3: |
| Reflectively Terminated 3-dB Coupler / 8.4: |
| Coupler Specifications / 8.5: |
| Measurements Using Directional Couplers / 8.6: |
| Network Analyzer Impedance Measurements / 8.7: |
| Two-Port Scattering Measurements / 8.8: |
| Branch Line Coupler / 8.9: |
| Hybrid Ring (Rat Race) Coupler / 8.10: |
| Wilkinson Divider / 8.11: |
| Filter Design / 9: |
| Voltage Transfer Function / 9.1: |
| Low-Pass Prototype / 9.2: |
| Butterworth or Maximally Flat Filter / 9.3: |
| Denormalizing the Prototype Response / 9.4: |
| High-Pass Filters / 9.5: |
| Bandpass Filters / 9.6: |
| Bandstop Filters / 9.7: |
| Chebyshev Filters / 9.8: |
| Phase and Group Delay / 9.9: |
| Filter Q / 9.10: |
| Diplexer Filters / 9.11: |
| Top-Coupled Bandpass Filters / 9.12: |
| Elliptic Filters / 9.13: |
| Distributed Filters / 9.14: |
| The Richards Transformation / 9.15: |
| Kuroda's Identities / 9.16: |
| Mumford's Maximally Flat Stub Filters / 9.17: |
| Filter Design with the Optimizer / 9.18: |
| Statistical Design and Yield Analysis / 9.19: |
| Using Standard Part Values |
| The Normal Distribution |
| Other Distributions |
| Transistor Amplifier Design / 10: |
| Unilateral Design / 10.1: |
| Evaluating S Parameters |
| Transistor Biasing |
| Evaluating RF Performance |
| Amplifier Stability / 10.2: |
| K Factor / 10.3: |
| Transducer Gain / 10.4: |
| Unilateral Gain Design / 10.5: |
| Unilateral Gain Circles / 10.6: |
| Input Gain Circles |
| Output Gain Circles |
| Simultaneous Conjugate Match Design / 10.7: |
| Various Gain Definitions / 10.8: |
| Operating Gain Design / 10.9: |
| Available Gain Design / 10.10: |
| Noise in Systems / 10.11: |
| Thermal Noise Limit |
| Other Noise Sources |
| Noise Figure of a Two-Port Network |
| Noise Factor of a Cascade |
| Noise Temperature |
| Low-Noise Amplifiers / 10.12: |
| Amplifier Nonlinearity / 10.13: |
| Gain Saturation |
| Intermodulation Distortion |
| Broadbanding with Feedback / 10.14: |
| Cascading Amplifier Stages / 10.15: |
| Amplifier Design Summary / 10.16: |
| Appendices |
| Symbols and Units / A.: |
| Complex Mathematics / B.: |
| Diameter and Resistance of Annealed Copper Wire by Gauge Size / C.: |
| Properties of Some Materials / D.: |
| Standard Rectangular Waveguides / E.: |
| Index |
図書
EB
