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Give an example of a function that is bounded and continuous on the interval [0, 1) but not uniformly continuous on this interval.
Continuous mapping on a compact metric space is uniformly continuousShowing $f(x)=x^4$ is not uniformly continuousIs function uniformly continuousA sequence of functions that is uniformly continuous, pointwise equicontinuous, but not uniformly equicontinuous when their domain is noncompactWhy is $f(x) = x^2$ uniformly continuous on [0,1] but not $mathbbR$Continuous but not uniformly continuous exampleHow to show a function is continuous but not uniformly continuous.Showing that a function is uniformly continuous but not LipschitzProve that $f=1/sqrtx$ is continuous on the interval $(0,1]$, but not uniformly continuous.Use continuity to show that $f(x)=x^3$ is uniformly continuous on $[0,1]$ but not $[0,infty]$Give an example of a non constant uniformly differentiable function
$begingroup$
My thoughts was to take $f(x) =cos(frac 1x) $ for all $ x in [0,1)$ as I know this function is continous from $[0,1)$ and is definitely not uniformly continuous as it oscilates non-uniformly. My trouble is with the proof.
To prove continuity would I:
Fix $x_0 in [0,1), epsilon>0.$ We will show that there exists $delta>0$ such that if $|x-x_0|<delta$ then $|cos(frac 1x) -cos(frac 1x_0)|<epsilon$
Now I am stuck as to how I could simplify $|cos(frac 1x) -cos(frac 1x_0)|$ or what $delta$ to choose. Any help would be appreciated.
real-analysis continuity examples-counterexamples uniform-continuity
edited 19 hours ago
José Carlos Santos
173k23133241
asked 20 hours ago
abcdefgabcdefg
525220
$endgroup$
|
show 2 more comments
$begingroup$
My thoughts was to take $f(x) =cos(frac 1x) $ for all $ x in [0,1)$ as I know this function is continous from $[0,1)$ and is definitely not uniformly continuous as it oscilates non-uniformly. My trouble is with the proof.
To prove continuity would I:
Fix $x_0 in [0,1), epsilon>0.$ We will show that there exists $delta>0$ such that if $|x-x_0|<delta$ then $|cos(frac 1x) -cos(frac 1x_0)|<epsilon$
Now I am stuck as to how I could simplify $|cos(frac 1x) -cos(frac 1x_0)|$ or what $delta$ to choose. Any help would be appreciated.
real-analysis continuity examples-counterexamples uniform-continuity
edited 19 hours ago
José Carlos Santos
173k23133241
asked 20 hours ago
abcdefgabcdefg
525220
$endgroup$
2
$begingroup$
You function is actually not defined at $x=0$.
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
What would you suggest as a function that I could use?
$endgroup$
– abcdefg
20 hours ago
$begingroup$
Why would you consider $cos (1/x)$ in the first place?
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
It was the first function I thought of that was continuous but not uniformly continuous.
$endgroup$
– abcdefg
20 hours ago
1
$begingroup$
@TheoBendit $frac1x-1$ is unbounded.
$endgroup$
– José Carlos Santos
19 hours ago
|
show 2 more comments
$begingroup$
My thoughts was to take $f(x) =cos(frac 1x) $ for all $ x in [0,1)$ as I know this function is continous from $[0,1)$ and is definitely not uniformly continuous as it oscilates non-uniformly. My trouble is with the proof.
To prove continuity would I:
Fix $x_0 in [0,1), epsilon>0.$ We will show that there exists $delta>0$ such that if $|x-x_0|<delta$ then $|cos(frac 1x) -cos(frac 1x_0)|<epsilon$
Now I am stuck as to how I could simplify $|cos(frac 1x) -cos(frac 1x_0)|$ or what $delta$ to choose. Any help would be appreciated.
real-analysis continuity examples-counterexamples uniform-continuity
edited 19 hours ago
José Carlos Santos
173k23133241
asked 20 hours ago
abcdefgabcdefg
525220
$endgroup$
My thoughts was to take $f(x) =cos(frac 1x) $ for all $ x in [0,1)$ as I know this function is continous from $[0,1)$ and is definitely not uniformly continuous as it oscilates non-uniformly. My trouble is with the proof.
To prove continuity would I:
Fix $x_0 in [0,1), epsilon>0.$ We will show that there exists $delta>0$ such that if $|x-x_0|<delta$ then $|cos(frac 1x) -cos(frac 1x_0)|<epsilon$
Now I am stuck as to how I could simplify $|cos(frac 1x) -cos(frac 1x_0)|$ or what $delta$ to choose. Any help would be appreciated.
real-analysis continuity examples-counterexamples uniform-continuity
real-analysis continuity examples-counterexamples uniform-continuity
edited 19 hours ago
José Carlos Santos
173k23133241
asked 20 hours ago
abcdefgabcdefg
525220
edited 19 hours ago
José Carlos Santos
173k23133241
asked 20 hours ago
abcdefgabcdefg
525220
edited 19 hours ago
José Carlos Santos
173k23133241
edited 19 hours ago
José Carlos Santos
173k23133241
edited 19 hours ago
José Carlos Santos
173k23133241
173k23133241
asked 20 hours ago
abcdefgabcdefg
525220
asked 20 hours ago
abcdefgabcdefg
525220
asked 20 hours ago
abcdefgabcdefg
525220
525220
2
$begingroup$
You function is actually not defined at $x=0$.
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
What would you suggest as a function that I could use?
$endgroup$
– abcdefg
20 hours ago
$begingroup$
Why would you consider $cos (1/x)$ in the first place?
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
It was the first function I thought of that was continuous but not uniformly continuous.
$endgroup$
– abcdefg
20 hours ago
1
$begingroup$
@TheoBendit $frac1x-1$ is unbounded.
$endgroup$
– José Carlos Santos
19 hours ago
|
show 2 more comments
2
$begingroup$
You function is actually not defined at $x=0$.
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
What would you suggest as a function that I could use?
$endgroup$
– abcdefg
20 hours ago
$begingroup$
Why would you consider $cos (1/x)$ in the first place?
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
It was the first function I thought of that was continuous but not uniformly continuous.
$endgroup$
– abcdefg
20 hours ago
1
$begingroup$
@TheoBendit $frac1x-1$ is unbounded.
$endgroup$
– José Carlos Santos
19 hours ago
2
2
$begingroup$
You function is actually not defined at $x=0$.
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
You function is actually not defined at $x=0$.
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
What would you suggest as a function that I could use?
$endgroup$
– abcdefg
20 hours ago
$begingroup$
What would you suggest as a function that I could use?
$endgroup$
– abcdefg
20 hours ago
$begingroup$
Why would you consider $cos (1/x)$ in the first place?
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
Why would you consider $cos (1/x)$ in the first place?
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
It was the first function I thought of that was continuous but not uniformly continuous.
$endgroup$
– abcdefg
20 hours ago
$begingroup$
It was the first function I thought of that was continuous but not uniformly continuous.
$endgroup$
– abcdefg
20 hours ago
1
1
$begingroup$
@TheoBendit $frac1x-1$ is unbounded.
$endgroup$
– José Carlos Santos
19 hours ago
$begingroup$
@TheoBendit $frac1x-1$ is unbounded.
$endgroup$
– José Carlos Santos
19 hours ago
|
show 2 more comments
2 Answers
2
active
oldest
votes
$begingroup$
Take $f(x)=cosleft(frac11-xright)$. If it was uniformly continuous, then, for each $varepsilon>0$, there would be some $delta>0$ such that $lvert x-yrvert<deltaimpliesbigllvert f(x)-f(y)bigrrvert<varepsilon$. But this is not true. Take $varepsilon=1$. Since there are values of $x$ arbitrarily close to $1$ such that $f(x)=1$ and there are values of $x$ arbitrarily close to $1$ such that $f(x)=-1$, then, no matter how small $delta$ is, you will always be able to find examples of numbers $x,yin[0,1)$ such that $lvert x-yrvert<delta$ and that $bigllvert f(x)-f(y)bigrrvert=2>varepsilon$
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
$endgroup$
add a comment |
$begingroup$
Here's some intuition:
The Heine-Cantor theorem tells us that any function between two metric spaces that is continuous on a compact set is also uniformly continuous on that set (see here for discussion). Next, if $f:X rightarrow Y$ is a uniformly continuous function, it is easy to show that the restriction of $f$ to any subset of $X$ is itself uniformly continuous*. Therefore, the functions $[0,1) to mathbbR$ that are continuous but not uniformly continuous are those functions that cannot be extended so as to be continuous on $[0,1]$.
For example, consider the function $f:[0,1) to mathbbR$ defined such that $f(x) = x$. We can extend $f$ to $[0,1]$ by defining $f(1) = 1$, and this extension is a continuous function over a compact set (hence it is uniformly continuous). So the restriction of this extension to $[0,1)$—i.e. the original function—is necessarily also uniformly continuous per (*) above.
How can we find a continuous function on $[0,1)$ that cannot be continuously extended to $[0,1]$? There are two ways:
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x rightarrow 1 f(x) = pm infty$
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x to 1 f(x)$ does not exist
Note that if $displaystyle lim_x to 1 f(x)$ exists, you can get a continuous extension by taking $f(1)$ to be that limit. Indeed, $displaystyle lim_x to c f(x) = f(c)$ is literally one of the definitions for continuity at the point $x=c$.
The first bullet is ruled out by the stipulation that $f$ be bounded, so moving on to the second bullet, we need to make sure $displaystyle lim_x to 1 f(x)$ does not exist. One way of doing this (the only way I believe) is to have $f$ oscillate infinitely rapidly as $x to 1$. It looks like this is what you were trying to exploit, and what José Carlos Santos did (+1) in his post: $displaystyle f(x) = cos left(frac11-x right)$.
$qquad qquad qquad qquad$ 
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
$endgroup$
add a comment |
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2 Answers
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2 Answers
2
active
oldest
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votes
$begingroup$
Take $f(x)=cosleft(frac11-xright)$. If it was uniformly continuous, then, for each $varepsilon>0$, there would be some $delta>0$ such that $lvert x-yrvert<deltaimpliesbigllvert f(x)-f(y)bigrrvert<varepsilon$. But this is not true. Take $varepsilon=1$. Since there are values of $x$ arbitrarily close to $1$ such that $f(x)=1$ and there are values of $x$ arbitrarily close to $1$ such that $f(x)=-1$, then, no matter how small $delta$ is, you will always be able to find examples of numbers $x,yin[0,1)$ such that $lvert x-yrvert<delta$ and that $bigllvert f(x)-f(y)bigrrvert=2>varepsilon$
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
$endgroup$
add a comment |
$begingroup$
Take $f(x)=cosleft(frac11-xright)$. If it was uniformly continuous, then, for each $varepsilon>0$, there would be some $delta>0$ such that $lvert x-yrvert<deltaimpliesbigllvert f(x)-f(y)bigrrvert<varepsilon$. But this is not true. Take $varepsilon=1$. Since there are values of $x$ arbitrarily close to $1$ such that $f(x)=1$ and there are values of $x$ arbitrarily close to $1$ such that $f(x)=-1$, then, no matter how small $delta$ is, you will always be able to find examples of numbers $x,yin[0,1)$ such that $lvert x-yrvert<delta$ and that $bigllvert f(x)-f(y)bigrrvert=2>varepsilon$
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
$endgroup$
add a comment |
$begingroup$
Take $f(x)=cosleft(frac11-xright)$. If it was uniformly continuous, then, for each $varepsilon>0$, there would be some $delta>0$ such that $lvert x-yrvert<deltaimpliesbigllvert f(x)-f(y)bigrrvert<varepsilon$. But this is not true. Take $varepsilon=1$. Since there are values of $x$ arbitrarily close to $1$ such that $f(x)=1$ and there are values of $x$ arbitrarily close to $1$ such that $f(x)=-1$, then, no matter how small $delta$ is, you will always be able to find examples of numbers $x,yin[0,1)$ such that $lvert x-yrvert<delta$ and that $bigllvert f(x)-f(y)bigrrvert=2>varepsilon$
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
$endgroup$
Take $f(x)=cosleft(frac11-xright)$. If it was uniformly continuous, then, for each $varepsilon>0$, there would be some $delta>0$ such that $lvert x-yrvert<deltaimpliesbigllvert f(x)-f(y)bigrrvert<varepsilon$. But this is not true. Take $varepsilon=1$. Since there are values of $x$ arbitrarily close to $1$ such that $f(x)=1$ and there are values of $x$ arbitrarily close to $1$ such that $f(x)=-1$, then, no matter how small $delta$ is, you will always be able to find examples of numbers $x,yin[0,1)$ such that $lvert x-yrvert<delta$ and that $bigllvert f(x)-f(y)bigrrvert=2>varepsilon$
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
answered 19 hours ago
José Carlos SantosJosé Carlos Santos
173k23133241
173k23133241
add a comment |
add a comment |
$begingroup$
Here's some intuition:
The Heine-Cantor theorem tells us that any function between two metric spaces that is continuous on a compact set is also uniformly continuous on that set (see here for discussion). Next, if $f:X rightarrow Y$ is a uniformly continuous function, it is easy to show that the restriction of $f$ to any subset of $X$ is itself uniformly continuous*. Therefore, the functions $[0,1) to mathbbR$ that are continuous but not uniformly continuous are those functions that cannot be extended so as to be continuous on $[0,1]$.
For example, consider the function $f:[0,1) to mathbbR$ defined such that $f(x) = x$. We can extend $f$ to $[0,1]$ by defining $f(1) = 1$, and this extension is a continuous function over a compact set (hence it is uniformly continuous). So the restriction of this extension to $[0,1)$—i.e. the original function—is necessarily also uniformly continuous per (*) above.
How can we find a continuous function on $[0,1)$ that cannot be continuously extended to $[0,1]$? There are two ways:
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x rightarrow 1 f(x) = pm infty$
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x to 1 f(x)$ does not exist
Note that if $displaystyle lim_x to 1 f(x)$ exists, you can get a continuous extension by taking $f(1)$ to be that limit. Indeed, $displaystyle lim_x to c f(x) = f(c)$ is literally one of the definitions for continuity at the point $x=c$.
The first bullet is ruled out by the stipulation that $f$ be bounded, so moving on to the second bullet, we need to make sure $displaystyle lim_x to 1 f(x)$ does not exist. One way of doing this (the only way I believe) is to have $f$ oscillate infinitely rapidly as $x to 1$. It looks like this is what you were trying to exploit, and what José Carlos Santos did (+1) in his post: $displaystyle f(x) = cos left(frac11-x right)$.
$qquad qquad qquad qquad$
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
$endgroup$
add a comment |
$begingroup$
Here's some intuition:
The Heine-Cantor theorem tells us that any function between two metric spaces that is continuous on a compact set is also uniformly continuous on that set (see here for discussion). Next, if $f:X rightarrow Y$ is a uniformly continuous function, it is easy to show that the restriction of $f$ to any subset of $X$ is itself uniformly continuous*. Therefore, the functions $[0,1) to mathbbR$ that are continuous but not uniformly continuous are those functions that cannot be extended so as to be continuous on $[0,1]$.
For example, consider the function $f:[0,1) to mathbbR$ defined such that $f(x) = x$. We can extend $f$ to $[0,1]$ by defining $f(1) = 1$, and this extension is a continuous function over a compact set (hence it is uniformly continuous). So the restriction of this extension to $[0,1)$—i.e. the original function—is necessarily also uniformly continuous per (*) above.
How can we find a continuous function on $[0,1)$ that cannot be continuously extended to $[0,1]$? There are two ways:
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x rightarrow 1 f(x) = pm infty$
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x to 1 f(x)$ does not exist
Note that if $displaystyle lim_x to 1 f(x)$ exists, you can get a continuous extension by taking $f(1)$ to be that limit. Indeed, $displaystyle lim_x to c f(x) = f(c)$ is literally one of the definitions for continuity at the point $x=c$.
The first bullet is ruled out by the stipulation that $f$ be bounded, so moving on to the second bullet, we need to make sure $displaystyle lim_x to 1 f(x)$ does not exist. One way of doing this (the only way I believe) is to have $f$ oscillate infinitely rapidly as $x to 1$. It looks like this is what you were trying to exploit, and what José Carlos Santos did (+1) in his post: $displaystyle f(x) = cos left(frac11-x right)$.
$qquad qquad qquad qquad$
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
$endgroup$
add a comment |
$begingroup$
Here's some intuition:
The Heine-Cantor theorem tells us that any function between two metric spaces that is continuous on a compact set is also uniformly continuous on that set (see here for discussion). Next, if $f:X rightarrow Y$ is a uniformly continuous function, it is easy to show that the restriction of $f$ to any subset of $X$ is itself uniformly continuous*. Therefore, the functions $[0,1) to mathbbR$ that are continuous but not uniformly continuous are those functions that cannot be extended so as to be continuous on $[0,1]$.
For example, consider the function $f:[0,1) to mathbbR$ defined such that $f(x) = x$. We can extend $f$ to $[0,1]$ by defining $f(1) = 1$, and this extension is a continuous function over a compact set (hence it is uniformly continuous). So the restriction of this extension to $[0,1)$—i.e. the original function—is necessarily also uniformly continuous per (*) above.
How can we find a continuous function on $[0,1)$ that cannot be continuously extended to $[0,1]$? There are two ways:
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x rightarrow 1 f(x) = pm infty$
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x to 1 f(x)$ does not exist
Note that if $displaystyle lim_x to 1 f(x)$ exists, you can get a continuous extension by taking $f(1)$ to be that limit. Indeed, $displaystyle lim_x to c f(x) = f(c)$ is literally one of the definitions for continuity at the point $x=c$.
The first bullet is ruled out by the stipulation that $f$ be bounded, so moving on to the second bullet, we need to make sure $displaystyle lim_x to 1 f(x)$ does not exist. One way of doing this (the only way I believe) is to have $f$ oscillate infinitely rapidly as $x to 1$. It looks like this is what you were trying to exploit, and what José Carlos Santos did (+1) in his post: $displaystyle f(x) = cos left(frac11-x right)$.
$qquad qquad qquad qquad$
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
$endgroup$
Here's some intuition:
The Heine-Cantor theorem tells us that any function between two metric spaces that is continuous on a compact set is also uniformly continuous on that set (see here for discussion). Next, if $f:X rightarrow Y$ is a uniformly continuous function, it is easy to show that the restriction of $f$ to any subset of $X$ is itself uniformly continuous*. Therefore, the functions $[0,1) to mathbbR$ that are continuous but not uniformly continuous are those functions that cannot be extended so as to be continuous on $[0,1]$.
For example, consider the function $f:[0,1) to mathbbR$ defined such that $f(x) = x$. We can extend $f$ to $[0,1]$ by defining $f(1) = 1$, and this extension is a continuous function over a compact set (hence it is uniformly continuous). So the restriction of this extension to $[0,1)$—i.e. the original function—is necessarily also uniformly continuous per (*) above.
How can we find a continuous function on $[0,1)$ that cannot be continuously extended to $[0,1]$? There are two ways:
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x rightarrow 1 f(x) = pm infty$
$qquad bullet quad$ Construct $f$ so that $displaystyle lim_x to 1 f(x)$ does not exist
Note that if $displaystyle lim_x to 1 f(x)$ exists, you can get a continuous extension by taking $f(1)$ to be that limit. Indeed, $displaystyle lim_x to c f(x) = f(c)$ is literally one of the definitions for continuity at the point $x=c$.
The first bullet is ruled out by the stipulation that $f$ be bounded, so moving on to the second bullet, we need to make sure $displaystyle lim_x to 1 f(x)$ does not exist. One way of doing this (the only way I believe) is to have $f$ oscillate infinitely rapidly as $x to 1$. It looks like this is what you were trying to exploit, and what José Carlos Santos did (+1) in his post: $displaystyle f(x) = cos left(frac11-x right)$.
$qquad qquad qquad qquad$
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
edited 11 hours ago
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
answered 19 hours ago
Kaj HansenKaj Hansen
27.7k43880
27.7k43880
add a comment |
add a comment |
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2
$begingroup$
You function is actually not defined at $x=0$.
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
What would you suggest as a function that I could use?
$endgroup$
– abcdefg
20 hours ago
$begingroup$
Why would you consider $cos (1/x)$ in the first place?
$endgroup$
– Arctic Char
20 hours ago
$begingroup$
It was the first function I thought of that was continuous but not uniformly continuous.
$endgroup$
– abcdefg
20 hours ago
1
$begingroup$
@TheoBendit $frac1x-1$ is unbounded.
$endgroup$
– José Carlos Santos
19 hours ago