Integrating with Infinite boundaries

SALAAH_BEDDIAF
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Homework Statement



Show that \int_{-\infty}^{+\infty} \frac{x-1}{x^5-1}dx = \frac{4\pi}{5}sin(\frac{2\pi}{5})

The Attempt at a Solution



This is actually a piece of work from a complex analysis module (not sure if it belongs in this part of the forum or in the analysis section)

I know that for any infinite bounded integrals you separate them to be \lim_{c\to -\infty} \int_c^0f(x)dx + \lim_{c\to +\infty}\int_0^cf(x)dx
and I have factorised x^5-1 = (x-1)(x^4 + x^3 + x^2 + x + 1)

Will I be integrating this as normal or is there a different way to do this if so please help me start :(.
 
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Since you found this problem in the context of complex analysis, you're probably meant to evaluate the integral by associating it with a complex integral, which you can evaluate using the residue theorem.
 
SALAAH_BEDDIAF, this is the correct forum section. I deleted your post in the other section.
 
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So I understand I will be evaluating this integral using Cauchy's Residue Theorem so I must find the singularities in the function, this is when (x-1)(x^4 + x^3 + x^2 + x + 1) = 0, from (x-1) we get a singularity to be 1, but I'm having difficulty finding (x^4 + x^3 + x^2 + x + 1) to be 0
 
The solutions of x5 - 1 = 0 are the 5th roots of unity. One of the roots is 1, which you already know. The other four are complex.
 
Mark44 said:
The solutions of x5 - 1 = 0 are the 5th roots of unity. One of the roots is 1, which you already know. The other four are complex.

so the roots of (x^4 + x^3 + x^2 + x + 1) are also the remaining roots of (x^5-1)?
 
Yes.
 
Okay, so I have all the roots now, as these roots are very difficult to be represented by fractions, can I use the approximate roots to find the residues or will I have to use the exact value?
 
If you write them in polar form, they're very simple.
 
  • #10
All n roots of z^n- 1= 0 lie on the circle |z|= 1 and are equally spaced around it. Since the denominator is fifth degree (odd) it has roots 1 and -1 but no roots on the imaginary axis. Of course, to use residues you need to integrate around a closed path. I would recommend integrating from "-iR" to "iR", for R> 1, along the imaginary axis, then on a semicircle back to "-iR". Finally, let R go to infinity.
 
  • #11
HallsofIvy said:
All n roots of z^n- 1= 0 lie on the circle |z|= 1 and are equally spaced around it. Since the denominator is fifth degree (odd) it has roots 1 and -1 ...
-1 isn't one of the roots. If n were even, it would be, but n is odd in this equation.
 
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