21: Electrical Transmission Lines

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21.1: Introduction
Transmission lines are used for carrying electromagnetic signals from one location to another. In the context of a radio, a transmission line is used to connect the radio's transceiver to the antenna. This chapter covers the theory and parameters associated with transmission lines.
21.2: Phasors
In many areas of engineering, signals are well-modeled as sinusoids. Also, devices that process these signals are often well-modeled as linear time-invariant (LTI) systems. The response of an LTI system to any linear combination of sinusoids is another linear combination of sinusoids having the same frequencies.
21.3: Introduction to Transmission Lines
Transmission lines are designed to support guided waves with controlled impedance, low loss, and a degree of immunity from EMI.
21.4: Types of Transmission Lines
21.5: Transmission Lines as Two-Port Devices
21.6: Lumped-Element Model
21.7: Telegrapher’s Equations
In this section, we derive the equations that govern the potential and current along a transmission line that is oriented along the \(z\) axis. For this, we will employ the lumped-element model.
21.8: Wave Equation for a Transmission Line
21.9: Characteristic Impedance of a Transmission Line
Characteristic impedance is the ratio of voltage to current for a wave that is propagating in single direction on a transmission line. This is an important parameter in the analysis and design of circuits and systems using transmission lines. In this section, we formally define this parameter and derive an expression for this parameter in terms of the equivalent circuit model.
21.10: Wave Propagation on a Transmission Line
21.11: Lossless and Low-Loss Transmission Lines
21.12: Voltage Reflection Coefficient
21.13: Standing Waves
A standing wave consists of waves moving in opposite directions. These waves add to make a distinct magnitude variation as a function of distance that does not vary in time.
21.14: Standing Wave Ratio
21.15: Parallel Wire Transmission Line
21.16: Attenuation in Coaxial Cable
In this section, we consider the issue of attenuation in coaxial transmission line.
21.17: Power Handling Capability of Coaxial Cable
The term “power handling” refers to maximum power that can be safely transferred by a transmission line. This power is limited because when the electric field becomes too large, dielectric breakdown and arcing may occur. This may result in damage to the line and connected devices, and so must be avoided.
21.18: Why 50 Ohms?
21.19: Conclusion

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