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I've done so many limit problems in calculus lately, but I can't wrap my mind around how to simplify this one in order to solve it:

$$ \lim_{x\rightarrow 2} \dfrac{x^3-8}{x^2-x-2} $$

I understand the $x^3-8$ factors down to $(x-2)(x^2+2x+4)$, but that still leaves us with $$ \lim_{x\rightarrow 2} \dfrac{(x-2)(x^2+2x+4)}{x^2-x-2}, $$ which I can't seem to find a way to simplify so that the denominator is not equal to 0.

In case anyone figures out themselves, the answer is 4 (I was given the answer - this is on a review sheet for an upcoming exam). Also, I tagged this as homework, even though it is not technically homework.

So if anyone could help point me in the right direction here, that would be very helpful.

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    The denominator factors as $x^2-x-2 = (x-2)(x+1)$. Does that help?2011-10-08
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    If you plug $2$ into a polynomial and get $0$, then $x-2$ is one of its factors. That's worth knowing. And if you plug $2$ in and get something other than $0$, then you won't get a $0$ in the denominator in a case like this, so then you could just plug $2$ into the whole expression and that's the limit.2011-10-08

3 Answers 3

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Hint: Note that $x^2-x-2=(x-2)(x+1)$.

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    And theres my answer.. I didn't even think that the denominator was factorable! How could I have missed that. Thank you - I will approve your answer when the time limit for which I can't approve any answer is up.2011-10-08
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    @Mike: If $p(x)$ is a polynomial, and $p(a)=0$, then $p(x)$ can **always** be factored as $p(x)=(x-a)q(x)$ for some polynomial $q(x)$. This is the [Factor Theorem](http://en.wikipedia.org/wiki/Factor_Theorem), so with these kinds of limits (a rational function that evaluates to $\frac{0}{0}$), you can *always* factor both the numerator and the denominator, cancel the factor, and try again.2011-10-08
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    Oh okay. That's sensible.2011-10-08
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$$\lim_{x \to 2}\dfrac{x^3-8}{x^2-x-2}=\lim_{x \to 2}\dfrac{(x^3-8)'}{(x^2-x-2)'}=...$$

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You can use the L`Hospital rule to find the answer. L´Hospital Rule

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    Why this late answer to a question with an accepted answer? And it's not like your answer is much better than the previous answers either.2013-03-30