## Limit by epsilon-delta proof: Example 2

This is the overdelayed continuation of the discussion on the $\epsilon-\delta$ definition of limits. In this post, we discuss another example.

Prove that the $\lim_{x \to 2} x^2 = 4$.

Recall that the definition states that the limit of $f(x) = L$ as $x$ approaches $a$ if for all $\epsilon > 0$, however small, there exists a $\delta > 0$ such that if $0 < |x - a| < \delta$, then $|f(x) - L| < \epsilon$.

From the example 1, we have learned that we should manipulate $|f(x)-L=|x^2 - 4|$, to make one of the expressions look like $|x-a|=|x-2|$. Solving,  we have

$|f(x) - L| = |x^2 - 4| = |(x+2)(x-2)| = |x+2||x-2|$.

Note that we have accomplished our goal, going back to the definition, this means that if $0 < x - 2 < \delta$, then $|x+2||x-2| < \epsilon$.

Now, it is not possible to divide both sides by $x + 2$ (making it $|x-2| < \frac{\epsilon}{|x+2|})$ because $x$ varies. This means that we have to find a constant $k$ such that $|x + 2| < k$. » Read more