Resonance

Resonance can be used to create zero impedance or zero admittance circuits at a particular resonant frequency, by either series or parallel connections of inductors and capacitors. However, care must be made not to exceed the maximum voltage or current ratings of the devices, especially in low-loss or high-${\displaystyle Q}$ circuits.

Series Resonant Circuits

Figure 1: A series RLC circuit.

Consider the series resonant RLC circuit shown in Fig. 1. We can calculate the total impedance seen by the source ${\displaystyle v_{S}}$, as:

${\displaystyle Z=R_{L}+j\omega L+{\frac {1}{j\omega C}}}$

(1)

Combining the imaginary terms of the impedance, we get:

${\displaystyle Z=R_{L}+j\left(\omega L-{\frac {1}{\omega C}}\right)}$

(2)

Resonant Frequency

We can see that the imaginary component of the impedance becomes zero at the resonant frequency, ${\displaystyle \omega _{0}}$, equal to:

${\displaystyle \omega _{0}={\frac {1}{\sqrt {LC}}}}$

(3)

Note that the cancellation is narrowband, since perfect cancellation occurs only at a single frequency. Thus, from the point of view of the voltage source ${\displaystyle v_{S}}$, the impedance ${\displaystyle Z}$ is purely real, and is equal to ${\displaystyle R_{L}}$. We can then calculate the current, ${\displaystyle i_{S}}$ as:

${\displaystyle \left.i_{S}\right|_{\omega =\omega _{0}}=\left.{\frac {v_{S}}{Z}}\right|_{\omega =\omega _{0}}={\frac {v_{S}}{R_{L}}}}$

(4)

We then use this current to calculate the voltage across the inductor and capacitor:

${\displaystyle \left.v_{L}\right|_{\omega =\omega _{0}}=i_{S}\cdot j\omega _{0}L={\frac {v_{S}}{R_{L}}}\cdot j\omega _{0}L=v_{S}\cdot jQ_{S}}$

(5)

${\displaystyle \left.v_{C}\right|_{\omega =\omega _{0}}=i_{S}\cdot {\frac {1}{j\omega _{0}C}}=-{\frac {v_{S}}{R_{L}}}\cdot j{\frac {1}{\omega _{0}C}}=-v_{S}\cdot jQ_{S}}$

(6)

Where ${\displaystyle Q_{S}}$ is the series circuit quality factor:

${\displaystyle Q_{S}={\frac {\omega _{0}L}{R_{L}}}={\frac {1}{\omega _{0}R_{L}C}}}$

(7)

Note that:

1. For small values of ${\displaystyle R_{L}}$ results in large values of ${\displaystyle Q_{S}}$, leading to large voltages across the inductor and capacitor.
2. The voltage across the inductor is exactly ${\displaystyle 180^{\circ }}$ out of phase with the capacitor voltage, thus cancelling each other out.

Parallel Resonant Circuits

Figure 2: A parallel RLC circuit.

For the parallel resonant RLC circuit in Fig. 2, the total admittance seen by the current source, ${\displaystyle i_{S}}$, is:

${\displaystyle Y={\frac {1}{R_{L}}}+j\omega C+{\frac {1}{j\omega L}}={\frac {1}{R_{L}}}+j\left(\omega C-{\frac {1}{\omega L}}\right)={\frac {1}{Z}}}$

(8)

The admittance becomes purely real at the resonant frequency, ${\displaystyle \omega _{0}={\tfrac {1}{\sqrt {LC}}}}$. Once again, we can calculate the voltage across ${\displaystyle R_{L}}$ as:

${\displaystyle \left.v_{S}\right|_{\omega =\omega _{0}}=\left.i_{S}\cdot Z\right|_{\omega =\omega _{0}}=i_{S}\cdot R_{L}}$

(9)

Thus, the currents through the inductor and capacitor can be expressed as:

${\displaystyle \left.i_{L}\right|_{\omega =\omega _{0}}={\frac {v_{S}}{j\omega _{0}L}}=-i_{S}\cdot j{\frac {R_{L}}{\omega _{0}L}}=-i_{S}\cdot jQ_{P}}$

(10)

${\displaystyle \left.i_{C}\right|_{\omega =\omega _{0}}=v_{S}\cdot j\omega _{0}C=i_{S}\cdot j\omega _{0}R_{L}C=i_{S}\cdot jQ_{P}}$

(11)

Where the parallel quality factor, ${\displaystyle Q_{P}}$ is equal to:

${\displaystyle Q_{P}={\frac {R_{L}}{\omega _{0}L}}=\omega _{0}R_{L}C}$

(12)

Similar to the series resonant circuit, we see that even though the currents through the reactances cancel out, the individual currents could be very large.