Difference between revisions of "Passive Matching Networks"

Revision as of 17:42, 1 September 2020

Controlling impedances in RF circuits are essential to maximize power transfer between blocks and to reduce reflections caused by impedance discontinuities along a signal path. In this module, we will define the quality factor, Q, for a device or a circuit, and use this Q to build circuits that modify the impedance seen across a port.

Device Quality Factor

The quality factor, Q, is a measure of how good a device is at storing energy. Thus, the lower the losses, the higher the Q. In general, if we can express the impedance or admittance of a device as ${\tfrac {1}{A+jB}}$ , the quality factor can then be expressed as $Q={\tfrac {B}{A}}$ . The imaginary component, $B$ represents the energy storage element, and the real component, $A$ , represents the loss (resistive) component.

For a series RC circuit, $Y={\tfrac {1}{R_{S}+j{\tfrac {1}{\omega C}}}}$ , we get

Q={\frac {\frac {1}{\omega C}}{R_{S}}}={\frac {1}{\omega R_{S}C}}

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-Controlling impedances in RF circuits are essential to maximize power transfer between blocks and to reduce reflections caused by impedance discontinuities along a signal path. In this module, we will define the quality factor, Q, for a device and a circuit, and use this Q to build circuits that modify the impedance seen across a port.
+Controlling impedances in RF circuits are essential to maximize power transfer between blocks and to reduce reflections caused by impedance discontinuities along a signal path. In this module, we will define the quality factor, Q, for a device or a circuit, and use this Q to build circuits that modify the impedance seen across a port.
 == Device Quality Factor ==
+The quality factor, Q, is a measure of how good a device is at storing energy. Thus, the lower the losses, the higher the Q. In general, if we can express the impedance or admittance of a device as <math>\tfrac{1}{A + jB}</math>, the quality factor can then be expressed as <math>Q=\tfrac{B}{A}</math>. The imaginary component, <math>B</math> represents the energy storage element, and the real component, <math>A</math>, represents the loss (resistive) component.
+For a series RC circuit, <math>Y =\tfrac{1}{R_S+j\tfrac{1}{\omega C}}</math>, we get
+{{NumBlk|::|<math>Q = \frac{\frac{1}{\omega C}}{R_S}=\frac{1}{\omega R_S C}</math>|{{EquationRef|1}}}}
 == Series-Parallel Conversions ==

Difference between revisions of "Passive Matching Networks"

Revision as of 17:42, 1 September 2020

Contents

Device Quality Factor

Series-Parallel Conversions

Basic Matching Networks

Loss in Matching Networks

T and Pi Matching Networks

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