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- [Instructor] What we're
going to do in this video
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is get some more practice
identifying when to use
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u-substitution and
picking an appropriate u.
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So let's say we have
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the indefinite integral of
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natural log of
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x to the,
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to the 10th power,
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all of that over x dx.
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Does u-substitution apply,
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and if so how would we
make that substitution?
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Well the key for u-substitution is to see,
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do I have some function
and its derivative?
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And you might immediately recognize
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that the derivative of natural log of x
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is equal to one over x.
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To make it a little bit clearer,
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I could write this as the integral of
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natural log of x to the 10th power
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times one over x dx.
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Now it becomes clear.
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We have some function, natural log of x,
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being raised to the 10th power,
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but we also have its
derivative right over here,
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one over x.
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So we could make the substitution.
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We could say that u
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is equal to the natural log of x.
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And the reason why I
picked natural log of x
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is because I see something,
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I see its exact derivative here,
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something close to its
derivative, in this case
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its exact derivative.
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And so then I could say,
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du dx,
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du dx is equal to one over x,
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which means that du
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is equal to one over x dx.
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And so here you have it.
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This right over here is du,
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and then this right over here is our u.
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And so this nicely simplifies to
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the integral of
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u to the 10th power,
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u to the 10th power du.
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And so you would evaluate what this is,
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find the antiderivative here,
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and then you would back-substitute
the natural log of x
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for u, to actually evaluate
this indefinite integral.
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Let's do another one.
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Let's say that we have
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the integral of,
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let's do something,
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let's do something interesting here.
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Let's say the integral of tangent x dx.
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Does u-substitution apply here?
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And at first you say well
I just have a tangent of x,
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where is its derivative?
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But one interesting thing to do is well
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we can rewrite tangent in
terms of sine and cosine.
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So we can write this as the integral of
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sine of x
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over cosine of x dx.
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And now you might say
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well where does u-substitution apply here?
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Well there's a couple of
ways to think about it.
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You could say the derivative
of sine of x is cosine of x,
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but you're now dividing by the derivative
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as opposed to multiplying by it.
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But more interesting you could say
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the derivative of cosine
of x is negative sine of x.
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We don't have a negative sine of x,
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but we can do a little bit of engineering.
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We can multiply by negative one twice.
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So we could say the negative
of the negative sine of x,
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and I stuck one of the you
could say negative ones
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outside of the integral,
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which comes straight from
our integration properties.
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This is equivalent.
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I can put a negative on the outside,
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a negative on the inside,
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so that this is the
derivative of cosine of x.
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And so now this is interesting.
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In fact let me rewrite this.
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This is going to be equal to negative,
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the negative integral,
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of one over cosine of x
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times negative sine of x dx.
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Now does it jump out at
you what our u might be?
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Well I have a cosine of
x in the denominator,
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and I have its derivative,
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so what if I made u equal to cosine of x?
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u is equal to cosine of x,
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and then du dx
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would be equal to negative sine of x.
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Or I could say
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that du is equal to negative sine of x dx.
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And just like that I have my du here,
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and this of course is my u.
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And so my whole thing
has now simplified to,
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it's equal to,
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the negative
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indefinite integral of one over u,
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one over u du.
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Which is a much easier
integral to evaluate,
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and then once you evaluate this,
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you back-substitute cosine of x for u.
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