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=====Review of Differential Equations in Circuits (5 minutes)=====
  * The differential equations defining charge (or current, if you wish) in basic circuits as a function of time are found using Kirchoff's Current Law and Kirchoff's Voltage Law.  Using Kirchoff's Voltage law, we can find that:

$$V_{L}=L\frac{dI}{dt} \; \; ,$$

and

$$V_{C}=\frac{Q}{C} \; \; .$$

Now, as an example of Kirchoff's Voltage Law, if we combine a capacitor and an inductor in series as shown below,

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 we find that

$$V_{C}+V_{L}=0 \; \; ,$$

which implies that

$$\frac{Q}{C}+L\frac{d^{2}Q}{dt^{2}}= 0 \; \; .$$

This differential equation will define what the charge in the circuit will do.  

So, the main strategy for solving for $Q(t)$ in a simple circuit made from inductors, capacitors, and resistors is to look for the differential equation and solve it.

**NOTE:** Resistors, capacitors, and inductors in series and parallel all have different properties from one another.  Remind students to find review these properties again.


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