Definitions:
Open Cover
Collection of open sets, whose union contains the current set
Subcover
Subcollection of the cover that is still the cover
Compact set
A topological space X is called compact if every open cover of X has a finite subcover
Bounded set
If there is a ball containing the set
Motivation
- Dealing with the infinity. Compact set is the next best thing after finite set
- Seeks to generalize the notion of a closed and bounded subset of Euclidean space
- Compactness is intrinsic property of the set
Theorems
1
Finite set is compact
2
Compact set is bounded and closed
3
For , is compact in is compact in
4
Closed subset of the compact set is compact
Heine -Borel
Bounded and closed sets in are compact
5
K compact every infinite subset has a limit point in K
Cantor
For the collection K of the compact subsets of X (some metric space). If every finite sub collection has a non empty intersection then the intersection of the entire collection is not empty
Proof: By contradiction using the compliment of K - open sets. No intersection⇒ compliment covers the whole space
6
K compact every collection of closed sets that has the Finite intersection property (FIP) has non empty intersection
7
Compactness is equivalent to sequential Compactness
8
Compact metric space is Complete metric space
9
Continuous image of the compact is compact