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Then, for t<3 y(t)=0
 
Then, for t<3 y(t)=0
 
For 3 < t < 5 y(t) = (e^-9 - e^-3(t-3)) / 3
 
For 3 < t < 5 y(t) = (e^-9 - e^-3(t-3)) / 3
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==> I think your lower bound should be 0 rather than 3 so that the answer to part 1 is <math>y(t) =\frac{1-e^{-3(t-3)}}{3}</math>
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For t>5 y(t) = (e^-3(t-5) - e^-3(t-3)) / 3
 
For t>5 y(t) = (e^-3(t-5) - e^-3(t-3)) / 3

Revision as of 22:40, 17 June 2008

Let x(t) = u(t-3) - u(t-5) and h(t) = e^-3tu(t)

A) y(t) = x(t)*h(t) I used the integral y(t) = $ \int_{-\infty}^\infty h(\tau)x(t-\tau)\,d\tau $ for simplicity.

Then, for t<3 y(t)=0 For 3 < t < 5 y(t) = (e^-9 - e^-3(t-3)) / 3


==> I think your lower bound should be 0 rather than 3 so that the answer to part 1 is $ y(t) =\frac{1-e^{-3(t-3)}}{3} $


For t>5 y(t) = (e^-3(t-5) - e^-3(t-3)) / 3

B y(t) = dx(t)/dt*h(t) = [delta(t-3) - delta(t-5)]*[e^-3t u(t)] For t < 3, y(t) = 0.

For 3 < t < 5, y(t) = $ \int_{-\infty}^\infty h(\tau)x(t-\tau)\,d\tau $ = $ \int_0^{t-3} h(\tau)x(t-\tau)\,d\tau $, so y(t) = [e^-9 - e^-3(t-3)] / 3.

For t > 5 y(t) = $ \int_{-\infty}^\infty h(\tau)x(t-\tau)\,d\tau $ = $ \int_{t-5}^{t-3} h(\tau)x(t-\tau)\,d\tau $, so y(t) = [e^-3(t-5) - e^-3(t-3)] / 3

I don't think that this is right, but I'm not sure what part I need to change.

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