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I am having trouble figuring how to rigorously prove limits as $x \to \infty$. For instance, how would I rigorously prove that

$\lim_{x \to \infty} x^2 = \infty$

I am stumped. It is, of course, obvious. However, I do not think simply stating such a fact qualifies are a proper proof. Please note that a link to a resource that explains this would suffice as help.

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    Pick some number $N.$ Is x^2>N for sufficiently large $x$?2012-09-25

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Let's play a game. The rules are as follows:

  • I'm going to pick a number $N$.
  • You're going to pick a number $M$.
  • I'm going to pick a number $x$ bigger than $M$.

If $x^2 > N$, you win. Otherwise, I win.

Do you think you'll win this game? If so, tell me what your strategy is.

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    @providence No, that would be against the rules, like White demanding to see Black's reply to his opening move before making it. But your question is very insightful, because in other cases one *can* vary the order and it makes an important difference. For example, a function $f$ is said to be *continuous* if, whenever I choose $x$ and $\epsilon$, and then you choose $\delta$, and I choose $y$ with |y-x|<\delta, then you win if |f(y)-f(x)|<\epsilon. But $f$ has the much stronger property of being *uniformly continuous* if you win even if I may postpone my choice of $x$ to the very end.2012-09-26
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You say "Let $N>0$ be given. I will now show that whenever $x$ is big enough, $x^2$ is bigger than $N$. To do this, I will find an $\delta>0$ such that whenever $x>\delta$, I will be able to show that $x^2>N$."

The interesting part is the details of how you produce the required $\delta$, which will vary from problem to problem. In this case one way to do it is to take $\delta = N$, because then whenever $x>\delta$, you know that $x^2 > \delta^2 = N^2 > N$. (Unless $N\le 1$, in which case taking $\delta = 1$ will do fine.)

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    Thanks; I have corrected the post.2012-09-26