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* The system is Linear. | * The system is Linear. | ||
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+ | We can break down the input <math> \,\ x(t) = cos(2t) </math> into <math> \,\ x(t) = \frac{1}{2} * (e</math><sup>(j2t)</sup> <math> \,\ + e</math><sup>(-j2t)</sup><math> \,\ )</math>. | ||
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+ | Now we can use the property of linearity to determine the output. | ||
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+ | We already know the outputs of the two individual parts of <math> cos(2t) </math>. All we have to do is add them together to find the output <math> z(t) </math>. | ||
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+ | <math> \,\ \frac{1}{2} * (e</math><sup>(j2t)</sup> <math> \,\ + e</math><sup>(-j2t)</sup><math> \,\ ) \rArr </math> SYSTEM <math> \,\ \rArr \frac{1}{2} * te</math><sup>(-2jt)</sup> + <math> \,\ \frac{1}{2} * te</math><sup>(2jt)</sup> | ||
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+ | <math> \,\ \frac{1}{2} * te</math><sup>(-2jt)</sup> + <math> \,\ \frac{1}{2} * te</math><sup>(2jt)</sup> <math> = t * \frac{1}{2} * (e</math><sup>(j2t)</sup> <math> \,\ + e</math><sup>(-j2t)</sup><math> \,\ ) </math> | ||
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+ | <math> t * \frac{1}{2} * (e</math><sup>(j2t)</sup> <math> \,\ + e</math><sup>(-j2t)</sup><math> \,\ ) = t*cos(2t) </math> | ||
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+ | Therefore, the input signal <math> \,\ x(t) = cos(2t) </math> yields an output signal of <math> \,\ z(t) = tcos(2t) </math> |
Latest revision as of 12:29, 16 September 2008
Basics of Linearity
We are given the following information:
- For input $ x(t) = e $ (2jt) the output $ y(t) = te $(-2jt).
- For input $ x(t) = e $ (-2jt) the output $ y(t) = te $(2jt).
- The system is Linear.
We can break down the input $ \,\ x(t) = cos(2t) $ into $ \,\ x(t) = \frac{1}{2} * (e $(j2t) $ \,\ + e $(-j2t)$ \,\ ) $.
Now we can use the property of linearity to determine the output.
We already know the outputs of the two individual parts of $ cos(2t) $. All we have to do is add them together to find the output $ z(t) $.
$ \,\ \frac{1}{2} * (e $(j2t) $ \,\ + e $(-j2t)$ \,\ ) \rArr $ SYSTEM $ \,\ \rArr \frac{1}{2} * te $(-2jt) + $ \,\ \frac{1}{2} * te $(2jt)
$ \,\ \frac{1}{2} * te $(-2jt) + $ \,\ \frac{1}{2} * te $(2jt) $ = t * \frac{1}{2} * (e $(j2t) $ \,\ + e $(-j2t)$ \,\ ) $
$ t * \frac{1}{2} * (e $(j2t) $ \,\ + e $(-j2t)$ \,\ ) = t*cos(2t) $
Therefore, the input signal $ \,\ x(t) = cos(2t) $ yields an output signal of $ \,\ z(t) = tcos(2t) $