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I am reading Martin Crossley's book - Essential Topology - basically to get an understanding of Topology and then to build a knowledge of Algebraic Topology! (That is the aim, anyway!)
On page 27, Example 3.33 (see attachment) Crossley is explaining the toplogising of \mathbb{R} P^2 where, of course, \mathbb{R} P^2 consists of lines through the origin in \mathbb {R}^3.
We take a subset of \mathbb{R} P^2 i.e. a collection of lines in \mathbb {R}^3, and then take a union of these lines to get a subset of \mathbb {R}^3.
Crossley then defines a subset of \mathbb{R} P^2 to be open if the corresponding subset of \mathbb {R}^3 is open.
Crossley then argues that there is a special problem with the origin, presumably because the intersection of a number of lines through the origin is the origin itself alone and this is not an open set in \mathbb {R}^3. (in a toplological space finite intersections of open sets must be open) [Is this reasoning correct?]
After resolving this problem by omitting the origin from \mathbb {R}^3 in his definition of openness, Crossley then asserts:
"Unions and intersections of \mathbb{R} P^2 correspond to unions and intersections of \mathbb {R}^3 - {0} ..."
But I cannot see that this is the case.
If we consider two lines l_1 and l_2 passing through the origin (see my diagram - topologising RP2 using open sets in R3 - attached) then the union of these is supposed to be an open set in \mathbb {R}^3 - {0} . But surely this would only be the case if we consider a complete cone of lines through the origin. With two lines - take a point x on one of them - then surely there is no open ball around this point in \mathbb {R}^3 - {0} ? ( again - see my diagram - topologising RP2 using open sets in R3 - attached) So the set is not open in \mathbb {R}^3 - {0}?
Can someone please clarify this for me?
Peter
On page 27, Example 3.33 (see attachment) Crossley is explaining the toplogising of \mathbb{R} P^2 where, of course, \mathbb{R} P^2 consists of lines through the origin in \mathbb {R}^3.
We take a subset of \mathbb{R} P^2 i.e. a collection of lines in \mathbb {R}^3, and then take a union of these lines to get a subset of \mathbb {R}^3.
Crossley then defines a subset of \mathbb{R} P^2 to be open if the corresponding subset of \mathbb {R}^3 is open.
Crossley then argues that there is a special problem with the origin, presumably because the intersection of a number of lines through the origin is the origin itself alone and this is not an open set in \mathbb {R}^3. (in a toplological space finite intersections of open sets must be open) [Is this reasoning correct?]
After resolving this problem by omitting the origin from \mathbb {R}^3 in his definition of openness, Crossley then asserts:
"Unions and intersections of \mathbb{R} P^2 correspond to unions and intersections of \mathbb {R}^3 - {0} ..."
But I cannot see that this is the case.
If we consider two lines l_1 and l_2 passing through the origin (see my diagram - topologising RP2 using open sets in R3 - attached) then the union of these is supposed to be an open set in \mathbb {R}^3 - {0} . But surely this would only be the case if we consider a complete cone of lines through the origin. With two lines - take a point x on one of them - then surely there is no open ball around this point in \mathbb {R}^3 - {0} ? ( again - see my diagram - topologising RP2 using open sets in R3 - attached) So the set is not open in \mathbb {R}^3 - {0}?
Can someone please clarify this for me?
Peter
