(New page: We are told that a system is linear and given inputs <math>\,x_1(t)=e^{2jt}\,</math> yields <math>\,y_1(t)=te^{-2jt}\,</math> <math>\,x_2(t)=e^{-2jt}\,</math> yields <math>\,y_2(t)=te^{2...)
 
 
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<math>\,x_2(t)=e^{-2jt}\,</math> yields <math>\,y_2(t)=te^{2jt}\,</math>
 
<math>\,x_2(t)=e^{-2jt}\,</math> yields <math>\,y_2(t)=te^{2jt}\,</math>
  
**initial given statements copied from
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**initial given statements copied from Jeff Kubascik
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Since,
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<math>\cos(2t) = \frac {e^{i2t} + e^{-i2t}} {2} </math>
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from the given input we know:
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y(t) = t*x(-t)
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If we multiply both t's in the equivalent cos(2t) by -1, then they simply switch places leaving the function unchanged.  Next, multiply by t and you are given your result.
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 +
y(t) = t*cos(2t)

Latest revision as of 14:27, 19 September 2008

We are told that a system is linear and given inputs

$ \,x_1(t)=e^{2jt}\, $ yields $ \,y_1(t)=te^{-2jt}\, $

$ \,x_2(t)=e^{-2jt}\, $ yields $ \,y_2(t)=te^{2jt}\, $

    • initial given statements copied from Jeff Kubascik

Since,

$ \cos(2t) = \frac {e^{i2t} + e^{-i2t}} {2} $

from the given input we know:

y(t) = t*x(-t)

If we multiply both t's in the equivalent cos(2t) by -1, then they simply switch places leaving the function unchanged. Next, multiply by t and you are given your result.

y(t) = t*cos(2t)

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