Quality Factor

Let us review the many definitions of the quality factor, ${\displaystyle Q}$. This context-dependent metric can allow us to gain important insights on the behavior and implementation of energy storage and loss in circuits.

Component Quality Factor

For a transfer function that we can write as:

${\displaystyle H\left(j\omega \right)={\frac {1}{R\left(\omega \right)+jX\left(\omega \right)}}}$

(1)

We can define the component quality factor, ${\displaystyle Q}$, as:

${\displaystyle Q=\left.{\frac {\text{energy stored}}{\text{average power dissipated}}}\right|_{\text{over a period of time}}={\frac {X\left(\omega \right)}{R\left(\omega \right)}}}$

(2)

Example: A Lossy Inductor

For a lossy inductor, modeled as an ideal inductor with a series resistance, ${\displaystyle R_{s}}$, we can write the admittance as:

${\displaystyle Y_{L}={\frac {I\left(\omega \right)}{V\left(\omega \right)}}={\frac {1}{R_{s}+j\omega L}}}$

(3)

The quality factor of the lossy inductor is then equal to:

${\displaystyle Q_{L}={\frac {\omega L}{R_{s}}}}$

(4)

Example: A Lossy Capacitor

For a lossy capacitor, modeled as an ideal capacitor in parallel with a resistance, ${\displaystyle R_{p}}$, we can write the impedance as:

${\displaystyle Z_{C}={\frac {V\left(\omega \right)}{I\left(\omega \right)}}={\frac {1}{{\frac {1}{R_{p}}}+j\omega C}}}$

(5)

The quality factor of the lossy capacitor is then equal to:

${\displaystyle Q_{C}=\omega C\cdot R_{p}}$

(6)

Pole Quality Factor

The quality factor of a pole is a good indicator of the "cost" of implementing a pole.

Band-Pass Filter Quality Factor