Reduction Formula (1 Viewer)

someth1ng · Apr 29, 2012

I can't seem to do any reduction formulae question, it just doesn't make any sense to me...

I need help with these:
Integral x^n (1+x^2)^0.5
Integral sin^5 (x)
Integral cos^6 (x)
Integral e^4n (1-x)^3

I just don't understand what the aim of this is, I know it's to make the powers smaller but I don't understand why it's needed or how to do it. What exactly does it mean by say I(n-1) or I(n-2) etc?

Help appreciated,
I find Integration harder than Polynomials, Volumes, Complex and Graphs...=/

Shadowdude · Apr 29, 2012

Why you need to do it? Well, cos(x)^6 and sin(x)^5 can't be easily solved directly. So you use a reduction formula to reduce the powers so in the end you just have to integrate a sin or a cos or something easy like that.

nightweaver066 · Apr 29, 2012

e.g.
$I_n = \int xsin^ndx$

$I_{n - 1} = \int xsin^{n-1}xdx$

$I_{n - 2} = \int xsin^{n - 2}xdx$

Your first question,

$Let ~ I_n = \int x^n\sqrt{1 + x^2}dx$

$= \int \frac{1}{3} x^{n - 1} d(\sqrt{(1 + x^2)^3})$

$= \frac{1}{3}x^{n - 1}\sqrt{(1 + x^2)^3} - \frac{1}{3}(n - 1)\int x^{n - 2}\sqrt{(1 + x^2)^3}dx$

$= \frac{1}{3}(x^{n - 1}\sqrt{(1 + x^2)^3} - (n - 1)\int x^{n - 2}\sqrt{1 + x^2}(1 + x^2)dx)$

$= \frac{1}{3}(x^{n - 1}\sqrt{(1 + x^2)^3} - (n - 1)\int x^{n - 2}\sqrt{1 + x^2} dx - (n - 1)\int x^n\sqrt{1 + x^2}dx)$

$= \frac{1}{3}(x^{n - 1}\sqrt{(1 + x^2)^3} - (n - 1)I_{n - 2} - (n - 1)I_n)$

$\therefore I_n + \frac{1}{3}(n - 1)I_n = \frac{1}{3}(x^{n - 1}\sqrt{(1 + x^2)^3} - (n - 1)I_{n -2})$

$\frac{n + 2}{3} I_n = \frac{1}{3}(x^{n - 1}\sqrt{(1 + x^2)^3} - (n - 1)I_{n - 2})$

$\therefore I_n = \frac{1}{n + 2}(x^{n - 1}\sqrt{(1 + x^2)^3} - (n - 1)I_{n - 2})$

Notice how the degree of the integral on the RHS reduces each time?

So if you're integrating something like $\int x^6\sqrt{1 + x^2}dx$ , you simply sub n = 6 in to that equation, and keep reusing that same formula til you end up with the integral.

juantheron · Apr 29, 2012

juantheron · Apr 29, 2012

juantheron · Apr 29, 2012

juantheron · Apr 29, 2012

someth1ng · May 1, 2012

So essentially, reduction formulas are doing anything to reduce the magnitude of the powers?

Carrotsticks · May 1, 2012

someth1ng said:
So essentially, reduction formulas are doing anything to reduce the magnitude of the powers?

Exactly, hence the name.

ie: We can't integrate sin^7(x) directly very easily, so we reduce the power to sin(x) or maybe even sin^0(x), which is = 1, then we integrate it since it is familiar.

Inference · May 1, 2012

Reduction formulas are based on recurrence relationships. What you need to realise is that we are essentially computing some integral $\int f(x, n) dx$ by continually reducing it down into an integral, $\int f(x, q)$ where $q<n$ . To find the integral, we first set n to its initial value while then reducing it down to lower indices until we can actually compute the expression with the lower index. Now initially, you may need a bit of wishful thinking to get used to doing these, however after a while you'll start to pick up tricks as with any integration technique.

Reduction Formula (1 Viewer)

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