Golden Rules: Difference between revisions

Latest revision as of 10:23, 14 March 2010

When analyzing operational amplifiers, there are a few rules that need to be taken into consideration in order to solve circuits using KVL or KCL.

Because the output voltage does not depend on the output current, the output impedance equals zero.
The input impedance $Z_{+}=Z_{-}=0$ .
When there is a negative feedback, both inputs have the same voltage. In other words, $V_{+}$ is equal to $V_{-}$ .
When solving circuits using the nodal analysis, write node equations at $V_{+}$ and $V_{-}$ , but not at $V_{o}$ .

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 When analyzing operational amplifiers, there are a few rules that need to be taken into consideration in order to solve circuits using KVL or KCL.
-# Because the output voltage does not depened on the output current, the output impedance equals zero.
+# Because the output voltage does not depend on the output current, the output impedance equals zero.
-# The input impedance <math>i_+=i_-=0</math>.
+# The input impedance <math>Z_+=Z_-=0</math>.
 # When there is a negative feedback, both inputs have the same voltage. In other words, <math>V_+</math> is equal to <math>V_-</math>.
-# When solving circuits using the nodes method, write node equations at <math>V_+</math> and <math>V_-</math>, but not at <math>V_o</math>.
+# When solving circuits using the nodal analysis, write node equations at <math>V_+</math> and <math>V_-</math>, but not at <math>V_o</math>.
 ==Sources==
@@ Line 11: / Line 11: @@
 ==Reviewer==
+[[Lau, Chris | Christopher Garrison Lau I]]
+*[[Vier, Michael | Michael Vier]]