What are the Laplace transforms of powers of y?

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SUMMARY

The discussion centers on the Laplace transforms of powers of a function y(t), specifically y^2 and y^3. It is established that there is no explicit formula for the Laplace transform of f(t)^n, as confusion arose between the notation for powers and derivatives. The participants agree that while linear operations are manageable with Laplace transforms, non-linear operations such as multiplication and powers complicate the process significantly, often requiring convolution techniques.

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Let's say you have a function y(t). You know how derivatives of y have their own Laplace transforms? Well I was wondering if powers of y such as y^2 or y^3 have their own unique Laplace transforms as well. If so , how do you calculate them (because plugging them into the usual integral doesn't seem to work)?
 
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Ssnow said:
On https://en.wikipedia.org/wiki/Laplace_transform, there is a table with properties of Laplace transform, one refer to the Laplace transform of ##f(t)^{n}## ...

Are you sure? I don't see such a formula. Unless you are mistaking the one for ##f^{(n)}(t)## which is the n'th derivative. I have never seen a formula for ##\mathcal L f(t)^n## and I don't think there is a general one.
 
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LCKurtz said:
Are you sure?

Yes sorry I confuse the notation, I fact there isn't and explicit formula for this ...
 
On that same wikipedia page, there seems to be a way to do that if we consider the Laplace transform of the multiplication of functions; we just take the function f(t) and multiply it n times.
 
Laplace transform is an efficient tool when linear operations are involves (sum, derivative, integral).
But it is not so, and generaly very complicated, when non-linear operations are involved (multiplication, division, power). Even in the simplest cases convolution is requiered, which is generaly arduous.
 
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