Why Does Trig Substitution Yield Different Integral Results?

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Jrlinton
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Homework Statement



∫8cos^3(2θ)sin(2θ)dθ

Homework Equations

The Attempt at a Solution


rewrote the integral as:
8∫(1-sin^2(2θ))sin(2θ)cos(2θ)dθ
u substitution with u=sin(2θ) du=2cos(2θ)dθ
4∫(1-u^2)u du= 4∫u-u^3 du
4(u^2/2-u^4/4)+C
undo substitution and simplify
2sin^2(2θ)-sin^4(2θ)+C
The book gives an answer of:
-cos^4(2θ)+C
 
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Jrlinton said:

Homework Statement



∫8cos^3(2θ)sin(2θ)dθ

Homework Equations

The Attempt at a Solution


rewrote the integral as:
8∫(1-sin^2(2θ))sin(2θ)cos(2θ)dθ
u substitution with u=sin(2θ) du=2cos(2θ)dθ
4∫(1-u^2)u du= 4∫u-u^3 du
4(u^2/2-u^4/4)+C
undo substitution and simplify
2sin^2(2θ)-sin^4(2θ)+C
The book gives an answer of:
-cos^4(2θ)+C

Check your answer by differentiating it to see if you get back to ##8 \cos^3 (2 \theta) \sin (2 \theta)##. Checking your answer by differentiation is something you should always do, every time.
 
I do in fact get my original expression. Thanks.
 
Jrlinton said:

Homework Statement



∫8cos^3(2θ)sin(2θ)dθ

Homework Equations

The Attempt at a Solution


rewrote the integral as:
8∫(1-sin^2(2θ))sin(2θ)cos(2θ)dθ
u substitution with u=sin(2θ) du=2cos(2θ)dθ
There's no need to rewrite the integral. In the original integral, use ordinary substitution with ##u = \cos(2\theta)##, and ##du = -2\sin(2\theta)d\theta##. Using this substitution leads directly to the book's answer.
Jrlinton said:
4∫(1-u^2)u du= 4∫u-u^3 du
4(u^2/2-u^4/4)+C
undo substitution and simplify
2sin^2(2θ)-sin^4(2θ)+C
The book gives an answer of:
-cos^4(2θ)+C
I second Ray's advice to always check your answer by differentiation.