Table of Contents
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Table of Contents
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Licensing
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1: Preliminary Concepts
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2: Electric and Magnetic Fields
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3: Transmission Lines
- 3.1: Introduction to Transmission Lines
- 3.2: Types of Transmission Lines
- 3.3: Transmission Lines as Two-Port Devices
- 3.4: Lumped-Element Model
- 3.5: Telegrapher’s Equations
- 3.6: Wave Equation for a TEM Transmission Line
- 3.7: Characteristic Impedance
- 3.8: Wave Propagation on a TEM Transmission Line
- 3.9: Lossless and Low-Loss Transmission Lines
- 3.10: Coaxial Line
- 3.11: Microstrip Line
- 3.12: Voltage Reflection Coefficient
- 3.13: Standing Waves
- 3.14: Standing Wave Ratio
- 3.15: Input Impedance of a Terminated Lossless Transmission Line
- 3.16: Input Impedance for Open- and Short-Circuit Terminations
- 3.17: Applications of Open- and Short-Circuited Transmission Line Stubs
- 3.18: Measurement of Transmission Line Characteristics
- 3.19: Quarter-Wavelength Transmission Line
- 3.20: Power Flow on Transmission Lines
- 3.21: Impedance Matching - General Considerations
- 3.22: Single-Reactance Matching
- 3.23: Single-Stub Matching
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4: Vector Analysis
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5: Electrostatics
- 5.1: Coulomb’s Law
- 5.2: Electric Field Due to Point Charges
- 5.3: Charge Distributions
- 5.4: Electric Field Due to a Continuous Distribution of Charge
- 5.5: Gauss’ Law - Integral Form
- 5.6: Electric Field Due to an Infinite Line Charge using Gauss’ Law
- 5.7: Gauss’ Law - Differential Form
- 5.8: Force, Energy, and Potential Difference
- 5.9: Independence of Path
- 5.10: Kirchoff’s Voltage Law for Electrostatics - Integral Form
- 5.11: Kirchoff’s Voltage Law for Electrostatics - Differential Form
- 5.12: Electric Potential Field Due to Point Charges
- 5.13: Electric Potential Field due to a Continuous Distribution of Charge
- 5.14: Electric Field as the Gradient of Potential
- 5.15: Poisson’s and Laplace’s Equations
- 5.16: Potential Field Within a Parallel Plate Capacitor
- 5.17: Boundary Conditions on the Electric Field Intensity (E)
- 5.18: Boundary Conditions on the Electric Flux Density (D)
- 5.19: Charge and Electric Field for a Perfectly Conducting Region
- 5.20: Dielectric Media
- 5.21: Dielectric Breakdown
- 5.22: Capacitance
- 5.23: The Thin Parallel Plate Capacitor
- 5.24: Capacitance of a Coaxial Structure
- 5.25: Electrostatic Energy
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6: Steady Current and Conductivity
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7: Magnetostatics
- 7.1: Comparison of Electrostatics and Magnetostatics
- 7.2: Gauss’ Law for Magnetic Fields - Integral Form
- 7.3: Gauss’ Law for Magnetism - Differential Form
- 7.4: Ampere’s Circuital Law (Magnetostatics) - Integral Form
- 7.5: Magnetic Field of an Infinitely-Long Straight Current-Bearing Wire
- 7.6: Magnetic Field Inside a Straight Coil
- 7.7: Magnetic Field of a Toroidal Coil
- 7.8: Magnetic Field of an Infinite Current Sheet
- 7.9: Ampere’s Law (Magnetostatics) - Differential Form
- 7.10: Boundary Conditions on the Magnetic Flux Density (B)
- 7.11: Boundary Conditions on the Magnetic Field Intensity (H)
- 7.12: Inductance
- 7.13: Inductance of a Straight Coil
- 7.14: Inductance of a Coaxial Structure
- 7.15: Magnetic Energy
- 7.16: Magnetic Materials
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8: Time-Varying Fields
- 8.1: Comparison of Static and Time-Varying Electromagnetics
- 8.2: Electromagnetic Induction
- 8.3: Faraday’s Law
- 8.4: Induction in a Motionless Loop
- 8.5: Transformers - Principle of Operation
- 8.6: Transformers as Two-Port Devices
- 8.7: The Electric Generator
- 8.8: The Maxwell-Faraday Equation
- 8.9: Displacement Current and Ampere’s Law
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9: Plane Waves in Loseless Media
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10: Appendices
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Index
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Glossary
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Detailed Licensing