Second Order Circuits: Difference between revisions

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= Series RLC Circuits =
= Series RLC Circuits =


== Unforced ==
== Natural Response ==
[[File:Unforced RLC Circuit.png|thumb|An unforced series RLC circuit]]
[[File:Unforced RLC Circuit.png|thumb|An unforced series RLC circuit]]
Consider an un-forced RLC circuit. We want to find <math>V_C</math>.
Consider an un-forced RLC circuit. We want to find <math>V_C</math>.
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= Parallel RLC Circuits =
= Parallel RLC Circuits =


== Unforced ==
== Natural Response ==
[[File:Parallel Unforced RLC Circuit.png|thumb|A parallel unforced RLC circuit]]
[[File:Parallel Unforced RLC Circuit.png|thumb|A parallel unforced RLC circuit]]
[[Category:Electrical Engineering]]
[[Category:Electrical Engineering]]

Revision as of 06:56, 8 March 2024

Second order circuits are circuits that have two energy storage elements, resulting in second-order differential equations.

One application of second order circuits is in timing computers. As we will see, an RLC circuit can generate a sinusoidal wave.

There are primarily two types of second order circuits:

  • Parallel RLC circuits
  • Series RLC circuits

Series RLC Circuits

Natural Response

An unforced series RLC circuit

Consider an un-forced RLC circuit. We want to find .

First, we can use KVL and KCL

Next, we can use and substitution to get

Changing the order and moving the constants,

Moving constants away from the first term to get a second-order differential equation,

Parallel RLC Circuits

Natural Response

A parallel unforced RLC circuit