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icycloud
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Sure, but how do you go from the 2nd to 3rd lines.Riviet said:
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icycloud
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Mm that's the method I had in mind, except you made a small mistake in the integration by parts.mountain.dew said:
The three trig formula for Products to Sums or Differences are:Mountain.Dew said:
2sinAsinB=cos(A-B)-cos(A+B)
2cosAcosB=cos(A-B)+cos(A+B)
2sinAcosB=sin(A+B)+sin(A-B)
It was probably just your lost memory from that partying after hsc.
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icycloud
Guest
Riviet said:
∫sin5x dx
= ∫(1-cos2x)2 sin(x) dx
= ∫(1-2cos2x+cos4x) d(-cos(x))
= ∫2cos2x - 1 - cos4x d(cos(x))
= 2/3 cos3x - cos(x) - cos5x/5 + C
#
= ∫(1-cos2x)2 sin(x) dx
= ∫(1-2cos2x+cos4x) d(-cos(x))
= ∫2cos2x - 1 - cos4x d(cos(x))
= 2/3 cos3x - cos(x) - cos5x/5 + C
#
Next Question:
Find ∫dx/(1+sin2x)
lfc_reds2003
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this man loves his maths..its great to see...
and he will dominate it for shizzy..GO TEAM
and he will dominate it for shizzy..GO TEAM
1/2 ∫ sin 2x^1/2 dx u = 2x^1/2icycloud said:
-1/2 ∫u sinu du
-1/2 {u * -cosu - ∫-cosu du}
ucosu/2 - 1/2 sinu + C
x^1/2 cos 2x^1/2 - 1/2 sin 2x^1/2 + C
I made an error somewhere in there, too late to go through my working though.
KeypadSDM
B4nn3d
Kinda dodgy method (I honestly can't see a way with any simple substitutions, so I had to do some manipulative algebra to get some trig terms I wanted to see):icycloud said:
K = 1/(1+sin2x)
=1/(cos2x+2sin2x)
=sec2x/(1 + 2tan2x)
So that's the dodgy step. It's all downhill from there with a u = Sqrt[2]tan[x] substitution, or you can do it directly by parts:
K = (d/dx(tan[x]))/(1 + 2tan2[x])
= (1/Sqrt[2])(d/dx(Sqrt[2]tan[x]))/(1 + (Sqrt[2]tan[x])2)
Thus:
I = ∫Kdx = (1/Sqrt[2])∫(d/dx(Sqrt[2]tan[x]))/(1 + (Sqrt[2]tan[x])2)dx
Now we've got something of the form, f'(x)/(1 + [f(x)]2)
Which integrates to give tan-1[f(x)]
Thus:
I = (1/Sqrt[2]) * tan-1[Sqrt[2]tan[x]] + C
= tan-1[Sqrt[2]tan[x]]/Sqrt[2] + C
=1/(cos2x+2sin2x)
=sec2x/(1 + 2tan2x)
So that's the dodgy step. It's all downhill from there with a u = Sqrt[2]tan[x] substitution, or you can do it directly by parts:
K = (d/dx(tan[x]))/(1 + 2tan2[x])
= (1/Sqrt[2])(d/dx(Sqrt[2]tan[x]))/(1 + (Sqrt[2]tan[x])2)
Thus:
I = ∫Kdx = (1/Sqrt[2])∫(d/dx(Sqrt[2]tan[x]))/(1 + (Sqrt[2]tan[x])2)dx
Now we've got something of the form, f'(x)/(1 + [f(x)]2)
Which integrates to give tan-1[f(x)]
Thus:
I = (1/Sqrt[2]) * tan-1[Sqrt[2]tan[x]] + C
= tan-1[Sqrt[2]tan[x]]/Sqrt[2] + C
Note that the original manipulation was quite lucky, I wouldn't have seen the substitution otherwise.
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icycloud
Guest
Nice method. Here is another way for those interested:KeypadSDM said:
1/(1+Sin[x]^2) = 1/(1 + (1/2 - Cos[2x]/2))
= 2/(3 - Cos[2x])
Then, use t = Tan[x], dt = t^2 + 1 dx
And proceed as with any t-substitution question, you should end up with the arctan integral dt/(2t^2+1), and come up with the same answer as Keypad's.
= 2/(3 - Cos[2x])
Then, use t = Tan[x], dt = t^2 + 1 dx
And proceed as with any t-substitution question, you should end up with the arctan integral dt/(2t^2+1), and come up with the same answer as Keypad's.
KeypadSDM
B4nn3d
Oh yeah, the t method. I forgot about that little nugget. It makes everything so easy.
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icycloud
Guest
Keypad, next question please . Preferably integration.
. Preferably integration.
KeypadSDM
B4nn3d
I don't know any good ones, I just like doing them.icycloud said:Keypad, next question please
Fine, I'll just go and look up some past papers. Are you HAPPY NOW?
Here is a nice integration question: (sorry for the crap presentation, dunno how to input definite integrals into here)
Find ∫from -pi/4 to pi/4[[sin^2(x)]/[1+e^(-x)]dx]
Find ∫from -pi/4 to pi/4[[sin^2(x)]/[1+e^(-x)]dx]
Hint: Prove that ∫from -pi/4 to 0 [[sin^2(x)]/[1+e^(-x)]dx]=∫from 0 to pi/4 [[sin^2(x)]/[1+e^x]dx] and use this fact to evaluate the definite integral
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KeypadSDM
B4nn3d
Didn't use the spoiler, but here's my method:Yip said:
set x = -y, and you'll find that:
I = ∫from -pi/4 to pi/4[[sin^2(x)]/[1+e^(-x)]dx]
=∫from -pi/4 to pi/4[[sin^2(y)]/[1+e^(y)]dx]
Thus, just looking at what's being integrated shows integrating the following two expressions is equivalent:
A(x) = sin2[x]/(1 + e-x)
B(x) = sin2[x]/(1 + ex)
= e-xsin2[x]/(e-x + 1)
That last one is by multiplying top and bottom by: e-x
And so:
e-xA(x) = B(x)
Therefore we have:
2I = ∫from -pi/4 to pi/4[A(x) + B(x)]dx
= ∫from -pi/4 to pi/4[(1 + e-x)A(x)]dx
= ∫from -pi/4 to pi/4[sin2[x]]dx
= 2∫from 0 to pi/4[sin2[x]]dx
[the last line occurs as the function being integrated is even]
So we have:
I = ∫from 0 to pi/4[sin2[x]]dx
=0.5∫from 0 to pi/4[1 - cos[2x]]dx
=0.5[x - sin[2x]/2]from 0 to pi/4
=0.5(pi/4 - sin[pi/2]/2 - 0 + 0/2)
=0.5(- 1/2 + pi/4)
=pi/8 - 1/4
I reckon that's right, I haven't checked though. [Using one of the approximations]
I = ∫from -pi/4 to pi/4[[sin^2(x)]/[1+e^(-x)]dx]
=∫from -pi/4 to pi/4[[sin^2(y)]/[1+e^(y)]dx]
Thus, just looking at what's being integrated shows integrating the following two expressions is equivalent:
A(x) = sin2[x]/(1 + e-x)
B(x) = sin2[x]/(1 + ex)
= e-xsin2[x]/(e-x + 1)
That last one is by multiplying top and bottom by: e-x
And so:
e-xA(x) = B(x)
Therefore we have:
2I = ∫from -pi/4 to pi/4[A(x) + B(x)]dx
= ∫from -pi/4 to pi/4[(1 + e-x)A(x)]dx
= ∫from -pi/4 to pi/4[sin2[x]]dx
= 2∫from 0 to pi/4[sin2[x]]dx
[the last line occurs as the function being integrated is even]
So we have:
I = ∫from 0 to pi/4[sin2[x]]dx
=0.5∫from 0 to pi/4[1 - cos[2x]]dx
=0.5[x - sin[2x]/2]from 0 to pi/4
=0.5(pi/4 - sin[pi/2]/2 - 0 + 0/2)
=0.5(- 1/2 + pi/4)
=pi/8 - 1/4
I reckon that's right, I haven't checked though. [Using one of the approximations]
Thats correct keypad ^^
It would be more efficient do it like this imo:
It would be more efficient do it like this imo:
Prove that ∫from -pi/4 to 0 [[sin^2(x)]/[1+e^(-x)]dx]=∫from 0 to pi/4 [[sin^2(x)]/[1+e^x]dx] using the substitution x=-t
Then u split the integral into [-pi/4,0] and [0,pi/4], and u will get
I=∫from 0 to pi/4 [[[sin^2(x)]/[1+e^(-x)]]+[[sin^2(x)]/[1+e^x]]dx
=∫from 0 to pi/4[[(1+e^x)/(1+e^x)]sin^2(x)]dx
=pi/8-1/4
Then u split the integral into [-pi/4,0] and [0,pi/4], and u will get
I=∫from 0 to pi/4 [[[sin^2(x)]/[1+e^(-x)]]+[[sin^2(x)]/[1+e^x]]dx
=∫from 0 to pi/4[[(1+e^x)/(1+e^x)]sin^2(x)]dx
=pi/8-1/4
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icycloud
Guest
Hey, just saw the question. Didn't look at the spoilers, here's my method:
Edit: OK I read the other two guys' posts. Seems like my method is pretty much the same as Keypad's. Yip's way is more efficient mmm...
Let I = ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 E^x / (1+E^x) dx
= ∫(-pi/4 --> pi/4) F(x) dx
Now, J = ∫(-pi/4 --> pi/4) F(-x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
Now, let u = -x, du=-dx, we have:
J = ∫(-pi/4 --> pi/4) F(u) du
= I
= ∫(-pi/4 --> pi/4) Sin[x]^2 E^x / (1+E^x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
Thus, I + J = 2I = ∫(-pi/4 --> pi/4) Sin[x]^2 E^x / (1+E^x) dx + ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 dx
Thus, I = 1/2∫(-pi/4 --> pi/4) Sin[x]^2 dx
= ∫(0 --> pi/4) Sin[x]^2 dx (symmetry)
= 1/2[x - 1/2Sin[2x]] (0 --> pi/4)
= pi/8 - 1/4
#
= ∫(-pi/4 --> pi/4) Sin[x]^2 E^x / (1+E^x) dx
= ∫(-pi/4 --> pi/4) F(x) dx
Now, J = ∫(-pi/4 --> pi/4) F(-x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
Now, let u = -x, du=-dx, we have:
J = ∫(-pi/4 --> pi/4) F(u) du
= I
= ∫(-pi/4 --> pi/4) Sin[x]^2 E^x / (1+E^x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
Thus, I + J = 2I = ∫(-pi/4 --> pi/4) Sin[x]^2 E^x / (1+E^x) dx + ∫(-pi/4 --> pi/4) Sin[x]^2 / (1+E^x) dx
= ∫(-pi/4 --> pi/4) Sin[x]^2 dx
Thus, I = 1/2∫(-pi/4 --> pi/4) Sin[x]^2 dx
= ∫(0 --> pi/4) Sin[x]^2 dx (symmetry)
= 1/2[x - 1/2Sin[2x]] (0 --> pi/4)
= pi/8 - 1/4
#
Edit: OK I read the other two guys' posts. Seems like my method is pretty much the same as Keypad's. Yip's way is more efficient mmm...
Haha yeh, one of my favourite topics in 4U (maybe because it's so easy relative to the other topics hehe).Riviet said:
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