How do you use the integral test to determine whether the following series converge of diverge $\sum \frac{n}{{(n^{2} + 1)}^{2}}$ $sum n/((n^2+1)^2)$ from n=1 to infinity? Thanks for the help !!! I have no idea on how to do these questions?

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How do you use the integral test to determine whether the following series converge of diverge $\sum \frac{n}{{(n^{2} + 1)}^{2}}$ $sum n/((n^2+1)^2)$ from n=1 to infinity? Thanks for the help !!! I have no idea on how to do these questions?

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Answer 1 · 2015-06-12T22:19:33

The series converges.

Explanation:

Let $f (x) = \frac{x}{{(x^{2} + 1)}^{2}}$ $f(x) = x/(x^2+1)^2$ .

In order to use the intergral test, $f (x)$ $f(x)$ must be positive and decreasing on $[p; + \infty [$ $[p;+oo[$ .

Let's study the sign of $f (x)$ $f(x)$ :
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$f (x)$ $f(x)$ is positive on $] 0; + \infty [$ $]0;+oo[$ .

Let's study the slope of $f (x)$ $f(x)$ :

To find the derivative of $f (x)$ $f(x)$ , we will use the formula :

$((h(x))/(g(x)))' = (h'(x)g(x) - h(x)g'(x))/g^2(x)$

$f'(x) = ((x^2+1)^2-4x^2(x^2+1))/(x^2+1)^4 = (-3x^2+1)/(x^2+1)^3$
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$f(x)$ is decreasing on $]1/sqrt(3);+oo[$

We want to use the integral test for n=1 to infinity. Since $f(x)$ is positive and decreasing on $]1/sqrt(3);+oo[$ , it is also true for $[1;+oo[$ .

$f(x) = x/(x^2+1)^2 = x(x^2+1)^(-2)$

To find the integral of $f(x)$ , we will use the formula :

$inth'(x)h^n(x)dx = 1/(n+1)h^(n+1)(x)$

$intf(x)dx = intx(x^2+1)^(-2)dx = 1/2int2x(x^2+1)^(-2)dx$

$= 1/2inth'(x)*h^(-2)(x)dx$ , where $h(x) = (x^2+1)$

$=1/2 * (1/((-2)+1)h^(-2+1)(x)) = -1/2h^(-1)(x)$

$= -1/2(x^2+1)^-1 = -1/(2(x^2+1)) = F(x)$

The series converges if $int_(1)^(+oo)f(x)dx$ exists.

$int_(1)^(+oo)f(x)dx = [F(x)]_(1)^(+oo) = ''F(+oo)'' - F(1)$

$= 0 - F(1) = -(-1/(1+1)^2) = +1/4$ .

The series converges.

Answer 2 · 2015-06-12T22:33:08

The integral test just says, basically:

By taking the integral of a positive, decreasing function $a_n$ of some series $sum a_n$ that works within the boundaries $[k, oo]$ , if the integral is finite, the sum converges.

$n/(n^2 + 1)^2$ is obviously decreasing since it's basically $n/n^4 = 1/n^3$ , which decreases as $n->oo$ . It's also certainly positive if $n > 0$ . Both conditions are satisfied.

So, integrate $n/(n^2 + 1)^2$ from $1$ to $oo$ . Just replace $n$ with $x$ .

$sum_(n=1)^(oo) n/(n^2 + 1)^2$ vs. $int_(1)^(oo) x/(x^2 + 1)^2dx$

Let:
$u = x^2 + 1$
$du = 2xdx$

$=> 1/2int_(1)^(oo) (2x)/(x^2 + 1)^2dx$

$= 1/2int_(1)^(oo) 1/(u^2)du$

$= 1/2 [-1/u]|_a^b$

$=> 1/2 (-1/(x^2+1))|_1^oo$

$= 1/2 [(-1/(oo^2+1)) - (-1/(1^2+1))]$

$= 1/2 [(0) - (-1/(2))] = 1/4$

The integral is finite, and therefore the series converges ( $oo^2 = oo, 1/(oo) = 0$ ).

This is really just using the idea that an integral over an interval is just the accumulation of an infinite number of thin intervals $dn$ .

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How do you use the integral test to determine whether the following series converge of diverge $\sum \frac{n}{{(n^{2} + 1)}^{2}}$ $sum n/((n^2+1)^2)$ from n=1 to infinity? Thanks for the help !!! I have no idea on how to do these questions?

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Explanation:

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How do you use the integral test to determine whether the following series converge of diverge sum n/((n^2+1)^2)∑n(n2+1)2sum n/((n^2+1)^2) from n=1 to infinity? Thanks for the help !!! I have no idea on how to do these questions?

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Explanation:

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How do you use the integral test to determine whether the following series converge of diverge $\sum \frac{n}{{(n^{2} + 1)}^{2}}$ $sum n/((n^2+1)^2)$ from n=1 to infinity? Thanks for the help !!! I have no idea on how to do these questions?