$f(x)= (f_1(x),f_2(x))$ is continuous on X $iff $ $f_1$ and $f_2$ are continuous
Let $X$ be any metric space. Let $f_1:Xto R$ and $F_2:Xto R $ be
defined. Then
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff $
$f_1$ and $f_2$ are continuous.
Instead of proving this via $epsilon -delta$ definition, can't we straight away use the sequential criterion to prove this?
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff$
$forall langle x_n rangle in X $ such that $langle x_n rangle to ain X$
we have $f(x_n)= (f_1(x_n),f_2(x_n)) to (f_1(a),f_2(a)) ; ; forall ain X$
$iff$
$f_1(x_n) to f1(a)$ and $f_2(x_n) to f_2(a)$
$iff$
Both $f_1$ and $f_2 $ are continuous on X.
general-topology continuity metric-spaces
add a comment |
Let $X$ be any metric space. Let $f_1:Xto R$ and $F_2:Xto R $ be
defined. Then
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff $
$f_1$ and $f_2$ are continuous.
Instead of proving this via $epsilon -delta$ definition, can't we straight away use the sequential criterion to prove this?
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff$
$forall langle x_n rangle in X $ such that $langle x_n rangle to ain X$
we have $f(x_n)= (f_1(x_n),f_2(x_n)) to (f_1(a),f_2(a)) ; ; forall ain X$
$iff$
$f_1(x_n) to f1(a)$ and $f_2(x_n) to f_2(a)$
$iff$
Both $f_1$ and $f_2 $ are continuous on X.
general-topology continuity metric-spaces
You proof is surely valid.
– Kavi Rama Murthy
Nov 25 at 5:21
you can also consider messing about with inclusions and projections, again to avoid writing much anything down
– qbert
Nov 25 at 5:24
add a comment |
Let $X$ be any metric space. Let $f_1:Xto R$ and $F_2:Xto R $ be
defined. Then
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff $
$f_1$ and $f_2$ are continuous.
Instead of proving this via $epsilon -delta$ definition, can't we straight away use the sequential criterion to prove this?
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff$
$forall langle x_n rangle in X $ such that $langle x_n rangle to ain X$
we have $f(x_n)= (f_1(x_n),f_2(x_n)) to (f_1(a),f_2(a)) ; ; forall ain X$
$iff$
$f_1(x_n) to f1(a)$ and $f_2(x_n) to f_2(a)$
$iff$
Both $f_1$ and $f_2 $ are continuous on X.
general-topology continuity metric-spaces
Let $X$ be any metric space. Let $f_1:Xto R$ and $F_2:Xto R $ be
defined. Then
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff $
$f_1$ and $f_2$ are continuous.
Instead of proving this via $epsilon -delta$ definition, can't we straight away use the sequential criterion to prove this?
$f:Xto R^2$
$f(x)= (f_1(x),f_2(x))$ is continuous on X
$iff$
$forall langle x_n rangle in X $ such that $langle x_n rangle to ain X$
we have $f(x_n)= (f_1(x_n),f_2(x_n)) to (f_1(a),f_2(a)) ; ; forall ain X$
$iff$
$f_1(x_n) to f1(a)$ and $f_2(x_n) to f_2(a)$
$iff$
Both $f_1$ and $f_2 $ are continuous on X.
general-topology continuity metric-spaces
general-topology continuity metric-spaces
edited Nov 25 at 5:21
asked Nov 25 at 5:20
So Lo
63719
63719
You proof is surely valid.
– Kavi Rama Murthy
Nov 25 at 5:21
you can also consider messing about with inclusions and projections, again to avoid writing much anything down
– qbert
Nov 25 at 5:24
add a comment |
You proof is surely valid.
– Kavi Rama Murthy
Nov 25 at 5:21
you can also consider messing about with inclusions and projections, again to avoid writing much anything down
– qbert
Nov 25 at 5:24
You proof is surely valid.
– Kavi Rama Murthy
Nov 25 at 5:21
You proof is surely valid.
– Kavi Rama Murthy
Nov 25 at 5:21
you can also consider messing about with inclusions and projections, again to avoid writing much anything down
– qbert
Nov 25 at 5:24
you can also consider messing about with inclusions and projections, again to avoid writing much anything down
– qbert
Nov 25 at 5:24
add a comment |
2 Answers
2
active
oldest
votes
Why is it true that $$(f_1(x_n), f_2(x_n)) rightarrow (f_1(a), f_2(a)) $$ if and only if $$f_1(x_n) rightarrow f_a(a) text{ and } f_s(x_n) rightarrow f_2(a)$$
If you've already proved this somewhere previously then good, you're re-using that proof to make your current proof simpler. But if you haven't already proved it then you've skipped over some important details, which are roughly equivalent to grinding out the $epsilon$-$delta$ proof.
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
add a comment |
Such a proof is indeed valid as soon as you know (and have proved) the following facts:
$f$ is continuous iff $f$ is sequentially continuous (this holds in metric spaces, and is commonly used in analysis).- A sequence $(a_n, b_n)_n $ in $mathbb{R}^2$ is convergent to $(a,b)$ iff $a_n to a$ and $b_n to b$.
Then still you could slightly rewrite it to prove the full equivalence (prove both directions separately):
Suppose $f_1$ and $f_2$ are continuous, to see that $f$ is (sequentially) continuous, let $(x_n)_n$ be a sequence in $X$ converging to $x in X$.
We then know by continuity of $f_1$ that $f(x_n) to f_1(x)$ and $f_2(x) to f_2(x)$, and so by 2. we know that $f(x_n) = (f_1(x_n), f_2(x_n)) to (f_1(x), f_2(x)) = f(x)$, as required. (This implication used the backward implication of 1. and the forward one of 2.)
Now suppose $f$ is continuous. We want to show $f_1$ and $f_2$ are continuous. let $x_n to x$ in $X$ again and we must show that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$. Observe that $$(f_1(x_n), f_2(x_n)) = f(x_n) to f(x)= (f_1(x), f_2(x))$$ by sequential continuity of $f$ and so by the other direction of 2. we have that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$, as required. (This implication used the forward implication of 1. and the backward one of 2.)
But of course the result itself is entirely independent of either metrics or sequences or even the finiteness of the product (just $2$ spaces here). In general topology this is just a consequence of the universal property of the product in the category of topological spaces.
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
add a comment |
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2 Answers
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2 Answers
2
active
oldest
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active
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Why is it true that $$(f_1(x_n), f_2(x_n)) rightarrow (f_1(a), f_2(a)) $$ if and only if $$f_1(x_n) rightarrow f_a(a) text{ and } f_s(x_n) rightarrow f_2(a)$$
If you've already proved this somewhere previously then good, you're re-using that proof to make your current proof simpler. But if you haven't already proved it then you've skipped over some important details, which are roughly equivalent to grinding out the $epsilon$-$delta$ proof.
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
add a comment |
Why is it true that $$(f_1(x_n), f_2(x_n)) rightarrow (f_1(a), f_2(a)) $$ if and only if $$f_1(x_n) rightarrow f_a(a) text{ and } f_s(x_n) rightarrow f_2(a)$$
If you've already proved this somewhere previously then good, you're re-using that proof to make your current proof simpler. But if you haven't already proved it then you've skipped over some important details, which are roughly equivalent to grinding out the $epsilon$-$delta$ proof.
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
add a comment |
Why is it true that $$(f_1(x_n), f_2(x_n)) rightarrow (f_1(a), f_2(a)) $$ if and only if $$f_1(x_n) rightarrow f_a(a) text{ and } f_s(x_n) rightarrow f_2(a)$$
If you've already proved this somewhere previously then good, you're re-using that proof to make your current proof simpler. But if you haven't already proved it then you've skipped over some important details, which are roughly equivalent to grinding out the $epsilon$-$delta$ proof.
Why is it true that $$(f_1(x_n), f_2(x_n)) rightarrow (f_1(a), f_2(a)) $$ if and only if $$f_1(x_n) rightarrow f_a(a) text{ and } f_s(x_n) rightarrow f_2(a)$$
If you've already proved this somewhere previously then good, you're re-using that proof to make your current proof simpler. But if you haven't already proved it then you've skipped over some important details, which are roughly equivalent to grinding out the $epsilon$-$delta$ proof.
answered Nov 25 at 5:39
JonathanZ
2,099613
2,099613
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
add a comment |
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
I will use the result that convergence in $R^n$ is component wise
– So Lo
Nov 25 at 6:06
add a comment |
Such a proof is indeed valid as soon as you know (and have proved) the following facts:
$f$ is continuous iff $f$ is sequentially continuous (this holds in metric spaces, and is commonly used in analysis).- A sequence $(a_n, b_n)_n $ in $mathbb{R}^2$ is convergent to $(a,b)$ iff $a_n to a$ and $b_n to b$.
Then still you could slightly rewrite it to prove the full equivalence (prove both directions separately):
Suppose $f_1$ and $f_2$ are continuous, to see that $f$ is (sequentially) continuous, let $(x_n)_n$ be a sequence in $X$ converging to $x in X$.
We then know by continuity of $f_1$ that $f(x_n) to f_1(x)$ and $f_2(x) to f_2(x)$, and so by 2. we know that $f(x_n) = (f_1(x_n), f_2(x_n)) to (f_1(x), f_2(x)) = f(x)$, as required. (This implication used the backward implication of 1. and the forward one of 2.)
Now suppose $f$ is continuous. We want to show $f_1$ and $f_2$ are continuous. let $x_n to x$ in $X$ again and we must show that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$. Observe that $$(f_1(x_n), f_2(x_n)) = f(x_n) to f(x)= (f_1(x), f_2(x))$$ by sequential continuity of $f$ and so by the other direction of 2. we have that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$, as required. (This implication used the forward implication of 1. and the backward one of 2.)
But of course the result itself is entirely independent of either metrics or sequences or even the finiteness of the product (just $2$ spaces here). In general topology this is just a consequence of the universal property of the product in the category of topological spaces.
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
add a comment |
Such a proof is indeed valid as soon as you know (and have proved) the following facts:
$f$ is continuous iff $f$ is sequentially continuous (this holds in metric spaces, and is commonly used in analysis).- A sequence $(a_n, b_n)_n $ in $mathbb{R}^2$ is convergent to $(a,b)$ iff $a_n to a$ and $b_n to b$.
Then still you could slightly rewrite it to prove the full equivalence (prove both directions separately):
Suppose $f_1$ and $f_2$ are continuous, to see that $f$ is (sequentially) continuous, let $(x_n)_n$ be a sequence in $X$ converging to $x in X$.
We then know by continuity of $f_1$ that $f(x_n) to f_1(x)$ and $f_2(x) to f_2(x)$, and so by 2. we know that $f(x_n) = (f_1(x_n), f_2(x_n)) to (f_1(x), f_2(x)) = f(x)$, as required. (This implication used the backward implication of 1. and the forward one of 2.)
Now suppose $f$ is continuous. We want to show $f_1$ and $f_2$ are continuous. let $x_n to x$ in $X$ again and we must show that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$. Observe that $$(f_1(x_n), f_2(x_n)) = f(x_n) to f(x)= (f_1(x), f_2(x))$$ by sequential continuity of $f$ and so by the other direction of 2. we have that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$, as required. (This implication used the forward implication of 1. and the backward one of 2.)
But of course the result itself is entirely independent of either metrics or sequences or even the finiteness of the product (just $2$ spaces here). In general topology this is just a consequence of the universal property of the product in the category of topological spaces.
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
add a comment |
Such a proof is indeed valid as soon as you know (and have proved) the following facts:
$f$ is continuous iff $f$ is sequentially continuous (this holds in metric spaces, and is commonly used in analysis).- A sequence $(a_n, b_n)_n $ in $mathbb{R}^2$ is convergent to $(a,b)$ iff $a_n to a$ and $b_n to b$.
Then still you could slightly rewrite it to prove the full equivalence (prove both directions separately):
Suppose $f_1$ and $f_2$ are continuous, to see that $f$ is (sequentially) continuous, let $(x_n)_n$ be a sequence in $X$ converging to $x in X$.
We then know by continuity of $f_1$ that $f(x_n) to f_1(x)$ and $f_2(x) to f_2(x)$, and so by 2. we know that $f(x_n) = (f_1(x_n), f_2(x_n)) to (f_1(x), f_2(x)) = f(x)$, as required. (This implication used the backward implication of 1. and the forward one of 2.)
Now suppose $f$ is continuous. We want to show $f_1$ and $f_2$ are continuous. let $x_n to x$ in $X$ again and we must show that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$. Observe that $$(f_1(x_n), f_2(x_n)) = f(x_n) to f(x)= (f_1(x), f_2(x))$$ by sequential continuity of $f$ and so by the other direction of 2. we have that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$, as required. (This implication used the forward implication of 1. and the backward one of 2.)
But of course the result itself is entirely independent of either metrics or sequences or even the finiteness of the product (just $2$ spaces here). In general topology this is just a consequence of the universal property of the product in the category of topological spaces.
Such a proof is indeed valid as soon as you know (and have proved) the following facts:
$f$ is continuous iff $f$ is sequentially continuous (this holds in metric spaces, and is commonly used in analysis).- A sequence $(a_n, b_n)_n $ in $mathbb{R}^2$ is convergent to $(a,b)$ iff $a_n to a$ and $b_n to b$.
Then still you could slightly rewrite it to prove the full equivalence (prove both directions separately):
Suppose $f_1$ and $f_2$ are continuous, to see that $f$ is (sequentially) continuous, let $(x_n)_n$ be a sequence in $X$ converging to $x in X$.
We then know by continuity of $f_1$ that $f(x_n) to f_1(x)$ and $f_2(x) to f_2(x)$, and so by 2. we know that $f(x_n) = (f_1(x_n), f_2(x_n)) to (f_1(x), f_2(x)) = f(x)$, as required. (This implication used the backward implication of 1. and the forward one of 2.)
Now suppose $f$ is continuous. We want to show $f_1$ and $f_2$ are continuous. let $x_n to x$ in $X$ again and we must show that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$. Observe that $$(f_1(x_n), f_2(x_n)) = f(x_n) to f(x)= (f_1(x), f_2(x))$$ by sequential continuity of $f$ and so by the other direction of 2. we have that $f_1(x_n) to f_1(x)$ and also $f_2(x_n) to f_2(x)$, as required. (This implication used the forward implication of 1. and the backward one of 2.)
But of course the result itself is entirely independent of either metrics or sequences or even the finiteness of the product (just $2$ spaces here). In general topology this is just a consequence of the universal property of the product in the category of topological spaces.
answered Nov 25 at 6:48
Henno Brandsma
105k346114
105k346114
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
add a comment |
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
I've proved the result in previous chapter that convergence in $R^n$ is component wise.
– So Lo
Nov 25 at 7:26
add a comment |
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You proof is surely valid.
– Kavi Rama Murthy
Nov 25 at 5:21
you can also consider messing about with inclusions and projections, again to avoid writing much anything down
– qbert
Nov 25 at 5:24