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Line 41: Line 41:
 
     I_2 = 3A\\
 
     I_2 = 3A\\
 
\end{align}
 
\end{align}
</math>
+
</math><br />
  
After finding <math> I_1 </math> and <math> I_2 </math> we can find <math> I_x </math>.
+
After finding <math> I_1 </math> and <math> I_2 </math> we can find <math> I_x </math>.<br />
<math>\begin
+
<math>\begin{align}
 
I_x = I_1 - I_2\\
 
I_x = I_1 - I_2\\
 
I_x = 2 - 3\\
 
I_x = 2 - 3\\
 
I_x = -1\\
 
I_x = -1\\
\end
+
\end{align}
 
</math>
 
</math>
  
Line 68: Line 68:
 
</math>
 
</math>
  
Finally, the last step would be to add up the two  <math> I_x </math><br /> we obtained by deactivating the voltage and current sources.
+
Finally, the last step would be to add up the two  <math> I_x </math> values we obtained by deactivating the voltage and current sources.
 
  <math> I_x = -1 + 2</math><br />
 
  <math> I_x = -1 + 2</math><br />
 
  <math> I_x = 1A</math><br />
 
  <math> I_x = 1A</math><br />

Latest revision as of 15:31, 2 May 2015


Superposition Practice

Practice question for ECE201: "Linear circuit analysis I"

By: Chinar Dhamija

Topic: Superposition



Question

Determine the value of $ I_x $ using superposition.

ECE201 P2.jpg


Answer

The circuit has two sources, a voltage and a current source. In order to find $ I_x $ we need to look at two instances.
1. Deactivate the voltage source (V = 0)
2. Deactivate the current source (I = 0)

Let's find $ I_x $ first by deactivating the voltage source as seen in the picture below.

ECE201 P3 2.jpg

We can find $ I_x $ by using loop analysis. The left loop can be $ I_1 $ and the right loop can be $ I_2 $.
When doing loop analysis we can come up with the following equation:
$ \begin{align} I_1: 10*I_1 + 20(I_1 - I_2) = 0\\ 30*I_1 = 20*I_2\\ I_2: I_2 = 3A\\ \end{align} $

After finding $ I_1 $ and $ I_2 $ we can find $ I_x $.
$ \begin{align} I_x = I_1 - I_2\\ I_x = 2 - 3\\ I_x = -1\\ \end{align} $

That is what we get for $ I_x $ if the voltage source is deactivated.

Now we need to do the same procedure but this time we will deactivate the current source; therefore, we will get the following circuit:

ECE201 P3 3.jpg

We can use source transformation to turn the voltage source into the current then use current division to solve for $ I_x $.
After doing source transformation we get the following circuit:

ECE201 P3 4.jpg

Now use current division to find $ I_x $.
$ \begin{align} I_x = \frac{1/10}{1/10 + 1/20} * 3\\ I_x = 2\\ \end{align} $

Finally, the last step would be to add up the two $ I_x $ values we obtained by deactivating the voltage and current sources.

$  I_x = -1 + 2 $
$ I_x = 1A $



Questions and comments

If you have any questions, comments, etc. please post them below

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