Difference between revisions of "Exercises:Mond - Topology - 1/Question 9"

Revision as of 18:25, 10 October 2016 (view source) Alec (Talk | contribs) (Saving work)		Revision as of 18:34, 10 October 2016 (view source) Alec (Talk | contribs) m (Altered formatting) Newer edit →
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	Show that {{M|\mathbb{RP}^2}} is [[Hausdorff]]		Show that {{M|\mathbb{RP}^2}} is [[Hausdorff]]
−	===Definitions===	+	====Definitions====
	* We denote by {{M|\pi:\mathbb{S}^2\rightarrow\frac{\mathbb{S}^2}{\sim} }} the [[canonical projection of the equivalence relation]], {{M|\sim}}. Note that this is a {{link|quotient map|topology}} when we consider {{M|\frac{\mathbb{S}^2}{\sim} }} with the [[quotient topology]].		* We denote by {{M|\pi:\mathbb{S}^2\rightarrow\frac{\mathbb{S}^2}{\sim} }} the [[canonical projection of the equivalence relation]], {{M|\sim}}. Note that this is a {{link|quotient map|topology}} when we consider {{M|\frac{\mathbb{S}^2}{\sim} }} with the [[quotient topology]].
−	===Solution outline===	+	====Solution outline====
	[[File:RP2isHausdorff.JPG|thumb|Diagram...]]We will deal with the [[open sets]], {{M|U}}, in terms of {{M|\pi^{-1}(U)}} (as by definition, {{M|U\in\mathcal{P}(\frac{\mathbb{S}^2}{\sim})}} is open in {{M|1=\frac{\mathbb{S}^2}{\sim} }} {{iff}} {{M|\pi^{-1}(U)}} is open in {{M|\mathbb{S}^2}}, which we consider with the [[subspace topology]] inherited from {{M|\mathbb{R}^3}} as usual) then we just have to find small enough open balls!		[[File:RP2isHausdorff.JPG|thumb|Diagram...]]We will deal with the [[open sets]], {{M|U}}, in terms of {{M|\pi^{-1}(U)}} (as by definition, {{M|U\in\mathcal{P}(\frac{\mathbb{S}^2}{\sim})}} is open in {{M|1=\frac{\mathbb{S}^2}{\sim} }} {{iff}} {{M|\pi^{-1}(U)}} is open in {{M|\mathbb{S}^2}}, which we consider with the [[subspace topology]] inherited from {{M|\mathbb{R}^3}} as usual) then we just have to find small enough open balls!
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	So we must be careful to make sure our balls do not overlap at all!		So we must be careful to make sure our balls do not overlap at all!
−	===Solution===	+	====Solution====
	We wish to show that {{M|\mathbb{RP}^2}} is [[Hausdorff]].		We wish to show that {{M|\mathbb{RP}^2}} is [[Hausdorff]].
	* Let {{M|a,b\in\mathbb{RP}^2}} be given such that {{M|1=a\ne b}}, then		* Let {{M|a,b\in\mathbb{RP}^2}} be given such that {{M|1=a\ne b}}, then

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Revision as of 18:34, 10 October 2016

Section B

Question 9

The real projective plane, [ilmath]\mathbb{RP}^2[/ilmath] is defined as the quotient of the sphere, [ilmath]\mathbb{S}^2[/ilmath], by the equivalence relation that defines (for [ilmath]x\in\mathbb{S}^2\subset\mathbb{R}^3[/ilmath]) [ilmath]x\sim -x[/ilmath], that is it identifies antipodal points.

Show that [ilmath]\mathbb{RP}^2[/ilmath] is Hausdorff

Definitions

• We denote by [ilmath]\pi:\mathbb{S}^2\rightarrow\frac{\mathbb{S}^2}{\sim} [/ilmath] the canonical projection of the equivalence relation, [ilmath]\sim[/ilmath]. Note that this is a quotient map when we consider [ilmath]\frac{\mathbb{S}^2}{\sim} [/ilmath] with the quotient topology.

Solution outline

We will deal with the open sets, [ilmath]U[/ilmath], in terms of [ilmath]\pi^{-1}(U)[/ilmath] (as by definition, [ilmath]U\in\mathcal{P}(\frac{\mathbb{S}^2}{\sim})[/ilmath] is open in [ilmath]\frac{\mathbb{S}^2}{\sim}[/ilmath] if and only if [ilmath]\pi^{-1}(U)[/ilmath] is open in [ilmath]\mathbb{S}^2[/ilmath], which we consider with the subspace topology inherited from [ilmath]\mathbb{R}^3[/ilmath] as usual) then we just have to find small enough open balls!

With this in mind, let [ilmath]a,b\in\mathbb{RP}^2[/ilmath] be given. We need to find two open sets (well... neighbourhoods will do... but open sets are neighbourhoods!), let's say [ilmath]U_a[/ilmath] and [ilmath]U_b[/ilmath] such that:

• [ilmath]a\in U_a[/ilmath], [ilmath]b\in U_b[/ilmath] and [ilmath]U_a\cap U_b=\emptyset[/ilmath]

Well:

• [ilmath]U_a[/ilmath] is open in [ilmath]\mathbb{RP}^2[/ilmath]

if and only if

• [ilmath]\pi^{-1}(U_a)[/ilmath] is open in [ilmath]\mathbb{S}^2[/ilmath]

if and only if

• there exists an open set, [ilmath]V_a[/ilmath] in [ilmath]\mathbb{R}^3[/ilmath] such that [ilmath]V_a\cap\mathbb{S}^2=\pi^{-1}(U_a)[/ilmath]

Of course, the open balls of [ilmath]\mathbb{R}^3[/ilmath] are a basis, so we can think of [ilmath]V_a[/ilmath] as a union of open balls, or possibly just an open ball (as basis sets themselves are open, and also as an open ball can be expressed as a union of open balls).

This changes the question into, in terms of [ilmath]a[/ilmath] and [ilmath]b[/ilmath], what size balls can we consider in [ilmath]\mathbb{R}^3[/ilmath] such that they're disjoint. There's a caveat here. This is what is shown in the diagram.

If [ilmath]a[/ilmath] and [ilmath]b[/ilmath] are "far apart" on [ilmath]\mathbb{RP}^2[/ilmath], it is entirely possible (in the pre-image under [ilmath]\pi[/ilmath]) that the antipodal point of one is near the other!

So we must be careful to make sure our balls do not overlap at all!

Solution

We wish to show that [ilmath]\mathbb{RP}^2[/ilmath] is Hausdorff.

• Let [ilmath]a,b\in\mathbb{RP}^2[/ilmath] be given such that [ilmath]a\ne b[/ilmath], then
  • there exist [ilmath]x,y\in\mathbb{S}^2[/ilmath] such that [ilmath]\pi^{-1}(a)=\{x,-x\}[/ilmath] and [ilmath]\pi^{-1}(b)=\{y,-y\}[/ilmath]

Notes

References