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We need to find which are uniform continuous (UC) on a) $(0,1)$ and b) $(0,\infty)$. I have done, could you confirm me, if I am wrong any where?

  1. $\frac{1}{(1-x)}$

  2. $\frac{1}{(2-x)}$

  3. $\sin x$

  4. $\sin(1/x)$

  5. $x^{1/2}$

  6. $x^3$

1) is not UC on a) because limit does not exist when $x\rightarrow 1$, on b) it is discontinous (disco) at $x=1$

2) is UC on a) and it is disco at $x=2$ so not UC on b)

3) is UC on a) and also on b) as we can show by the inequality $|\sin x-\sin y|<|x-y|$

4) is not UC on a) as limit does not exist, and also not UC on b) I am not clear enough for this one.

5) is UC on a) and not UC on b) as derivative is not bounded near $0$

6) is UC on a) and not UC on b) as derivative is not bounded.

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    @draks,DonAntonio thank you very much2012-06-09

1 Answers 1

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I think you need to take another look at (5). If it fails to be UC on $(0,\infty)$ because the derivative is unbounded near $0$, it should fail to be UC on $(0,1)$ for the same reason. If it is UC on $(0,1)$, then the same reasoning should show that it is UC on $(0,\infty)$--since in this case, it is UC on $[1,\infty)$ and is continuous on $(0,\infty)$. I leave it to you to determine which of your arguments is correct.

As for the rest, it looks good, for the most part. One can make an even nicer argument for $\sin x$ being UC, since it is continuous (so UC) on $[0,2\pi]$ and periodic with period $2\pi$, so UC on $\mathbb{R}$, so UC on any subset of $\mathbb{R}$.

Something that may help you to clear up (4): A function $f:E\to\mathbb{R}$ (with $E\subseteq\mathbb{R}$) fails to be uniformly continuous if there is some $\varepsilon>0$ and some sequences $\{x_n\}$ and $\{y_n\}$ of points of $E$ such that $x_n-y_n\to 0$ and such that $|f(x_n)-f(y_n)|\geq\varepsilon$ for all $n$. Consider the points that cause $\sin(1/x)$ to maximize as $x\to 0$ and the points that cause $\sin(1/x)$ to minimize as $x\to 0$, and that should give you your sequences.

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    Cameron thank you for the sum up...for $4$ we can take $x_n=\frac{1}{2n\pi}$ and $y_n=\frac{1}{(2n+1)\pi}$2012-06-09