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13 votes
13 votes
Find the inverse Laplace of
\displaystyle{L^(-1)\left \{ (1)/(s^3) + (1)/(s)\right \}}

User OJBakker
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1 Answer

24 votes
24 votes

Compute the Laplace transform of
f(t)=t^n, where
n is a non-negative integer.


\displaystyle L\left\{t^n\right\} = I_n = \int_0^\infty t^n e^(-st) \, dt

Integrate by parts with


u=t^n \implies du = nt^(n-1) \, dt


dv = e^(-st) \, dt \implies v = -\frac1s e^(-st)


\displaystyle I_n = \frac ns \int_0^\infty t^(n-1) e^(-st) \, dt = \frac ns I_(n-1)

By substitution,


\displaystyle I_n = \frac ns I_(n-1) = (n(n-1))/(s^2) I_(n-2) = \cdots = (n(n-1)\cdots(n-(k-1)))/(s^k) I_(n-k)

so that for
k=n, we end up with


\displaystyle I_n = (n(n-1)\cdots1)/(s^n) I_0 = (n!)/(s^n) \int_0^\infty e^(-st) \, dt = (n!)/(s^(n+1))

We then have the inverse transform relation


\displaystyle L^(-1)\left\{ \frac1{s^n} \right\} = (t^(n-1))/((n-1)!)

and so


L^(-1)\left\{ \frac1{s^3} + \frac1s \right\} = (t^2)/(2!) + (0!)/(t^0) = \boxed{\frac{t^2}2 + 1}

User Amadi
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