Laplace transform heavyside function

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SUMMARY

The discussion focuses on finding the Laplace transform of the function sin(wt) u(t - b) and the application of the time-shifting property in Laplace transforms. The Laplace transform is defined as \(\mathcal{L}\{f(t)\} = \int_0^{\infty} e^{-st}f(t) dt\). The participants clarify that for the function g(t) u(t-b), the integral can be split, leading to simplifications based on the properties of the unit step function. Additionally, they discuss the transform of (t-1)^4 u(t) and suggest using the formula L[f(t-a)u(t-a)] = e^{-as}F(s) for time shifts, while noting that binomial expansion may be necessary for certain forms.

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Homework Statement


find the transform of
<br /> sin (wt) u(t - b)<br />


I have to get it into the form for the time shift but I do not know how to deal with the unit function

help appreciated
 
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The Laplace transform is defined as:
\mathcal{L}\lbrace f(t)\rbrace = \int_0^{\infty} e^{-st}f(t) dt
Now, let's put in
f(t) = g(t) u(t-b)
where u(t-b) is zero for t<b and 1 for t>b. Plugging this in:\int_0^{\infty} e^{-st}f(t) dt = \int_0^{\infty} e^{-st}g(t) u(t-b) dt

Now split this integral into two parts:

\int_0^{\infty} e^{-st}g(t) u(t-b) dt = \int_0^{b} e^{-st}g(t) u(t-b) dt + \int_b^{\infty} e^{-st}g(t) u(t-b) dt

The first integral vanishes, since u(t-b) is zero on the integration domain. In the second the u-function is simply 1. I'll let you solve the remaining steps.
 
ahhh cool


now let's say I have
<br /> (t-1)^4 u(t)<br />

function is 1 from 0 < t < 1 and (t-1)^4 for t> 1

I can easily do the transform of t^4 how would i play with it to just do a time shift after the transform or do I have to go the integral route and do parts?
 
If you do not have to work it out from first principles (and I do not think you have to), you could do it by using this L-transform formula:
L[f(t-a)u(t-a)] = e^{-as}F(s) \text{ where F(s) is L.T. of } f(t).

Of course in the case of (t-1)^4 u(t), it's not in a form which yields itself readily to that formula. In such a case you may have to work out the binomial expansion of (t-1)^4 before applying that formula.
 

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