Normalization of time independent wave function

Skullmonkee
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Homework Statement


normalize the wave function \Psi(x)= Acos(\Pi*x/a) to show that A=\sqrt{2/a}

The Attempt at a Solution


i don't know how to get that answer as all i can tell, normalizing gives:
-A^{2}pi^{2}2x/a^{2} * sin (pix/a)

However this does not give the right answer for A
Any help pointing out what I've missed would be great.
 
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Hi Skullmonkee,

Let me ask you a question first:

What expression "defines" the normalization of a wavefunction?
 
Do you mean this?

\int\Psi^{*}\Psi dx=1

\int Acos(\pi x/a)*Acos(\pi x/a)dx

= \int A^{2}cos^{2}(\pi x/a)

But I am not sure where to go from here?
 
What are the limits of integration? I.e., over what range of x is the wavefunction defined?
 
You need to plug in the limits of integration. You can't normalize a wave function using indefinite integration.
 
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