Difference between revisions of "Exercises:Mond - Topology - 1/Question 7"

Revision as of 13:19, 8 October 2016

Section B

Question 7

Let $D^2$ denote the closed unit disk in $\mathbb{R}^2$ and define an equivalence relation on $D^2$ by setting $x_1\sim x_2$ if $\Vert x_1\Vert=\Vert x_2\Vert=1$ ("collapsing the boundary to a single point"). Show that $\frac{D^2}{\sim}$ is homeomorphic to $\mathbb{S}^2$ - the sphere.

Hint: first define a surjection $(:D^2\rightarrow\mathbb{S}^2)$ mapping all of $\partial D^2$ to the north pole. This may be defined using a good picture or a formula.

Solution

The idea is to double the radius of

$D^2$ , then pop it out into a hemisphere, then pull the rim to a point

Picture showing the "expanding

$D^2$ ", the embedding-in-

$\mathbb{R}^3$ part, and the "popping out"

Definitions:

$H$ denotes the hemisphere in my picture.
$E:D^2\rightarrow H$ is the composition of maps in my diagram that take $D^2$ , double its radius, then embed it in $\mathbb{R}^3$ then "pop it out" into a hemisphere. We take it as obvious that it is a homeomorphism
$f':H\rightarrow\mathbb{S}^2$ , this is the map in the top picture. It takes the hemisphere and pulls the boundary/rim in (along the blue lines) to the north pole of the red sphere. $f'(\partial H)=(0,0,1)\in\mathbb{R}^3$ , it should be clear that for all $x\in H-\partial H$ that $f'(x)$ is intended to be a point on the red sphere and that $f'\big\vert_{H-\partial H}$ is injective. It is also taken as clear that $f'$ is surjective
Note: Click the pictures for a larger version
$\frac{D^2}{\sim}$ and $D^2/\sim$ denote the quotient space, with this definition we get a canonical projection, $\pi:D^2\rightarrow D^2/\sim$ given by $\pi:x\mapsto [x]$ where $[x]$ denotes the equivalence class of $x$
Lastly, we define $f:D^2\rightarrow\mathbb{S}^2$ to be the composition of $E$ and $f'$ , that is: $f:=f'\circ E$ , meaning $f:x\mapsto f'(E(x))$

The situation is shown diagramatically below:

$\xymatrix{ D^2 \ar[d]_\pi \ar[r]^E \ar@/^1.5pc/[rr]^{f:=f'\circ E} & H \ar[r]^{f'} & \mathbb{S}^2 \\ \frac{D^2}{\sim} }$

Outline of the solution:

We then want apply the passing to the quotient theorem to yield a commutative diagram: $\xymatrix{ D^2 \ar[d]_\pi \ar[r]^E \ar@/^1.5pc/[rr]^{f} & H \ar[r]^{f'} & \mathbb{S}^2 \\ \frac{D^2}{\sim} \ar@{.>}[urr]_{\bar{f} } }$
- The commutative diagram part merely means that $f=\bar{f}\circ\pi$ ^{[Note 1]}. We get $f=\bar{f}\circ\pi$ as a result of the passing-to-the-quotient theorem.
Lastly, we will show that $\bar{f}$ is a homeomorphism using the compact-to-Hausdorff theorem

Solution:

Notes

Jump up ↑ Technically a diagram is said to commute if all paths through it yield equal compositions, this means that we also require $f=f'\circ E$ , which we already have by definition of $f$ !

References

[1] Jump up ↑ Technically a diagram is said to commute if all paths through it yield equal compositions, this means that we also require $f=f'\circ E$ , which we already have by definition of $f$ !

[Note 1]

@@ Line 6: / Line 6: @@
 ====Solution====
 {{float-right|{{Exercises:Mond - Topology - 1/Pictures/Q7 - 1}}}}
-Comments:
+Definitions:
-# Suppose we take the hind and find a surjection, {{M|f:D^2\rightarrow\mathbb{S}^2}}, what would we do next? {{link|Passing to the quotient|topology}} again! Then, as already mentioned, invoke the [[compact-to-Hausdorff theorem]] to yield a [[homeomorphism]]
+* {{M|H}} denotes the hemisphere in my picture.
+* {{M|E:D^2\rightarrow H}} is the composition of maps in my diagram that take {{M|D^2}}, double its radius, then embed it in {{M|\mathbb{R}^3}} then "pop it out" into a hemisphere. We take it as obvious that it is a [[homeomorphism]]
+* {{M|f':H\rightarrow\mathbb{S}^2}}, this is the map in the top picture. It takes the hemisphere and pulls the boundary/rim in (along the blue lines) to the north pole of the red sphere. {{M|1=f'(\partial H)=(0,0,1)\in\mathbb{R}^3}}, it should be clear that for all {{M|x\in H-\partial H}} that {{M|f'(x)}} is intended to be a point on the red sphere and that {{M|1=f'\big\vert_{H-\partial H} }} is [[injective]]. It is also taken as clear that {{m|f'}} is [[surjective]]
+* '''Note: '''{{Note|Click the pictures for a larger version}}
+* {{M|\frac{D^2}{\sim} }} and {{M|D^2/\sim}} denote the [[quotient topology|quotient space]], with this definition we get a [[canonical projection of the quotient topology|canonical projection]], {{M|\pi:D^2\rightarrow D^2/\sim}} given by {{M|\pi:x\mapsto [x]}} where {{M|[x]}} denotes the [[equivalence class]] of {{M|x}}
+* Lastly, we define {{M|f:D^2\rightarrow\mathbb{S}^2}} to be the [[function composition|composition]] of {{M|E}} and {{M|f'}}, that is: {{M|1=f:=f'\circ E}}, meaning {{M|f:x\mapsto f'(E(x))}}
+The situation is shown diagramatically below:
+* <span><m>\xymatrix{ D^2 \ar[d]_\pi \ar[r]^E \ar@/^1.5pc/[rr]^{f:=f'\circ E} & H \ar[r]^{f'} & \mathbb{S}^2 \\ \frac{D^2}{\sim} }</m></span>
+'''Outline of the solution:'''
+* We then want apply the {{link|passing to the quotient|topology}} theorem to yield a [[commutative diagram]]: <span><m>\xymatrix{ D^2 \ar[d]_\pi \ar[r]^E \ar@/^1.5pc/[rr]^{f} & H \ar[r]^{f'} & \mathbb{S}^2 \\ \frac{D^2}{\sim} \ar@{.>}[urr]_{\bar{f} } }</m></span>
+** The commutative diagram part merely means that {{M|1=f=\bar{f}\circ\pi}}<ref group="Note">Technically a diagram is said to commute if all paths through it yield equal compositions, this means that we also require {{M|1=f=f'\circ E}}, which we already have by definition of {{M|f}}!</ref>. We get {{M|1=f=\bar{f}\circ\pi}} as a result of the passing-to-the-quotient theorem.
+* Lastly, we will show that {{M|\bar{f} }} is a [[homeomorphism]] using the [[compact-to-Hausdorff theorem]]
+'''Solution:'''
 <div style="clear:both;"></div>
 <noinclude>

Difference between revisions of "Exercises:Mond - Topology - 1/Question 7"

Revision as of 13:19, 8 October 2016

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Section B

Question 7

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