(→Basics of Linearity) |
(→Basics of Linearity) |
||
| Line 14: | Line 14: | ||
<math>\ \dfrac{t e^{-2 i x} + t e^{2 i x}}{2} </math> | <math>\ \dfrac{t e^{-2 i x} + t e^{2 i x}}{2} </math> | ||
but | but | ||
| − | :<math>e^{2 x i}=\cos 2x + i \sin 2x \, </math> and <math>e^{-2 x i}=\cos 2x - i \sin 2x \, </math> so the response is | + | :<math>e^{2 x i}=\cos 2x + i \sin 2x \, </math> and |
| + | :<math>e^{-2 x i}=\cos 2x - i \sin 2x \, </math> | ||
| + | :so the response is equal to | ||
| − | :<math> | + | :<math>\cos 2t </math> |
Revision as of 08:34, 18 September 2008
Basics of Linearity
Given
- $ e^{2 x i}=t e^{-2 x i}\, $
- $ e^{-2 x i}=t e^{2 x i}\, $
- The Signal is Linear
- $ \cos x = \dfrac{e^{i x}+e^{-i x}}{2} $
- $ \cos 2x = \dfrac{e^{2 i x}+e^{-2 i x}}{2} $
The Systems response to $ \cos 2x $ is $ \ \dfrac{t e^{-2 i x} + t e^{2 i x}}{2} $ but
- $ e^{2 x i}=\cos 2x + i \sin 2x \, $ and
- $ e^{-2 x i}=\cos 2x - i \sin 2x \, $
- so the response is equal to
- $ \cos 2t $
