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Would you like to do some challenging integration questions? (1 Viewer)

.ben

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1.

dx
∫ ---------------
(4x3-3x)sqrt(1-x2)

2.

Let tn=∫[pi/2-->0]xsinnxdx
Prove that tn=1/n2+[(n-1)/n]*tn-2

3.

Prove In=∫[pi/2-->0]cos2nxdx=[pi(2n)!/22n+1(n!)2]

4.

Given that If I2n+1=∫[1-->0]x2n+1ex2dx
Prove that
I2n+1=e/2-nI2n-1


That's all for now thanks.
 

_ShiFTy_

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Hmm...

Q1...confusing me too much :)

Q2 - took me some time to get the first step right but finally got it!

Q3 - wtf... i see factorial stuff, i run away and hide

Q4 - similar to Q4 but easier to spot


thx for these questions ben, might come in handy for my assessment tmrw :)
 
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_ShiFTy_

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Hehe, good luck!

btw, do you have the answer to Q1...and any hints for Q3?
 

.ben

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yeh you too

sorry don't have any of the answers.
 

Yip

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Shifty:
ara~.~ didnt notice the reciprocal -_- rather dodgy typesetting :p
q3: Obtain a reduction formula for the integral by taking the cosx part out and itnegrate it, then apply it a billion times:p
 
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_ShiFTy_

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Yip said:
Shifty:
q1: factorize x out and make substitution t^2=x^2-1, then it should come out pretty quickly
But then you need a 2x.dx on top, which we dont have
 

.ben

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I fed question 1 to integrator. it came out with a really long log expression??!?!
 

hyparzero

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There are 5 log terms actually, and without an elegant method, it would take approximately 3 pages to work it out :p

∫(1/((4*x^3-3*x)*sqrt(1-x^2)), x) =

1/3*ln(3*tan(1/2*arcsin(x))-sqrt(3))-1/3*ln(-3*tan(1/2*arcsin(x))+3*sqrt(3))
-1/3*ln(3*tan(1/2*arcsin(x))+3*sqrt(3))+1/3*ln(-3*tan(1/2*arcsin(x))-sqrt(3))-1/3*ln(1/x-sqrt(1-x^2)/x) + C
 

_ShiFTy_

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Just a general question about Q3, how can you get factorials from doing integration involving reduction?
 
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who_loves_maths

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.ben said:
1.

_________________dx
∫ __________________________________
__(4x3-3x)sqrt(1-x2)

2.

Let tn=∫[pi/2-->0]xsinnxdx
Prove that tn=1/n2+[(n-1)/n]*tn-2

3.

Prove In=∫[pi/2-->0]cos2nxdx=[pi(2n)!/22n+1(n!)2]

4.

Given that If I2n+1=∫[1-->0]x2n+1ex2dx
Prove that
I2n+1=e/2-nI2n-1
Hi .ben, hope this isn't too late of a reply if you actually need(ed) solutions to any of these questions.

QUESTION 1: Find ∫dx/[x(4x2 -3).Sqrt(1-x2)]

Make the substitution Sqrt(1-x2) = u ; -xdx/Sqrt(1-x2) = du

I = -∫du/(1-u2)(1-4u2)

then use the method of partial fractions to obtain :

I = (1/6)∫du/(1+u) + (1/6)∫du/(1-u) - (2/3)∫du/(1+2u) - (2/3)∫du/(1-2u)
= (1/6)ln|1+u| - (1/6)ln|1-u| - (1/3)ln|1+2u| + (1/3)ln|1-2u| + C
= (1/6)ln|(1+u)/(1-u)| + (1/3)ln|(1-2u)/(1+2u)| + C

Alternatively, you can also use standard integrals to assist during, say, an exam.


QUESTION 2: Show In = 1/n2 + ((n -1)/n)In-2

In = {pi/2 -> 0}∫xSinnx dx = ∫(xSinn-2x)Sin2x dx

where Sin2(t) = 1 - Cos2(t) :

In = ∫xSinn-2x dx - ∫xSinn-2x Cos2x dx

---> ∫xSinn-2x Cos2x dx = In-2 - In ____________________ (1)

Now, apply integration by parts to the original integral In:

let u = xSinn-1x , and dv = Sin(x) dx

you get:

In = [-xSinn-1x Cos(x)]{pi/2 -> 0} + ∫Cos(x)[(n-1)xSinn-2x Cos(x) + Sinn-1x] dx

but [-xSinn-1x Cos(x)]{pi/2 -> 0} = 0

In = (n-1)∫xSinn-2x Cos2x dx + ∫Sinn-1x Cos(x) dx

but {pi/2 -> 0}∫Sinn-1x Cos(x) dx = (1/n)[Sinnx]{pi/2 -> 0}= 1/n

i.e. In = (n-1)∫xSinn-2x Cos2x dx + 1/n ____________________ (2)

Finally, substitute (1) into (2) :

In = (n-1)(In-2 - In) + 1/n

---> In = 1/n^2 + ((n -1)/n)In-2


QUESTION 3: Show In = (pi.(2n)!)/(22n+1 n!2)

Proceed by induction.

1) n = 1
LHS = I1 = {pi/2 -> 0}∫Cos2x dx = pi/4 = RHS.
n = 1 true.

2) Assume truth for n = k; to show for n = (k+1);

3) Consider:

Ik+1 := i2(k+1) and Ik := i2k ; where ":=" denotes "is equivalent to", and im denotes the m-th term of the recurrence integral: im = ∫Cosmx dx

We proceed to use the reduction formula for the Cosine recurrence integral:

im = [(1/m)Cosm-1x Sin(x)]{pi/2 -> 0} + ((m-1)/m).im-2

but [(1/m)Cosm-1x Sin(x)]{pi/2 -> 0} = 0

---> im = ((m-1)/m).im-2

So we have:

Ik+1 = i2k+2 = ((2k+1)/(2k+2)).i2k = ((2k+1)/(2k+2))Ik

Using our initial assumption for n = k:

Ik+1 = ((2k+1)/(2k+2))[(pi.(2k)!)/(22k+1 k!2)]

multiply top and bottom by (2k+2) to obtain:

Ik+1 = [(2k+1)(2k+2)/(2k+2)2].[(pi.(2k)!)/(22k+1 k!2)]
= (pi.(2(k+1))!)/(22(k+1)+1 (k+1)!2)

Therefore, the case of n = (k+1) is true when n = k is true.

This completes the proof.


QUESTION 4: Prove I2n+1 = e/2 - 2nI2n-1

I2n+1 = {1 -> 0}∫x2n+1 ex2 dx = (1/2)∫(x2n(2xex2)) dx

Proceed via integration by parts:

let u = x2n , and dv = 2xex2 dx ---> du = 2nx2n-1 , and v = ex2

I2n+1 = (1/2)(x2n ex2){1 -> 0} - 2n∫x2n-1 ex2 dx

but (x2n ex2){1 -> 0} = e , and ∫x2n-1 ex2 dx = I2n-1

-----> I2n+1 = e/2 - 2nI2n-1


Hope this may help, cheers.


P.S.1. I believe there is a 2 in front of the 'nI2n-1' term in Question 4.

P.S.2. Apologies for any incorrect/unsightly typesetting.
 

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