Assignment 6
... c) Any two connected components are either equal or disjoint. The space is partitioned into its connected components. The space is connected if and only if it has only one connected component. d) The same statements as above with connected replaced by path connected. e) The closure of a connected s ...
... c) Any two connected components are either equal or disjoint. The space is partitioned into its connected components. The space is connected if and only if it has only one connected component. d) The same statements as above with connected replaced by path connected. e) The closure of a connected s ...
Topology Semester II, 2015–16
... there is an element C ∈ C such that C ⊂ Bm . Similarly, since B is a basis of X, there exists an n ∈ N such that Bn ⊂ C. Now, for every pair of indices n, m for which it is possible, choose a Cn,m such that Bn ⊂ Cn,m ⊂ Bm . Obviously, it is a countable sub collection of C and we claim that it is als ...
... there is an element C ∈ C such that C ⊂ Bm . Similarly, since B is a basis of X, there exists an n ∈ N such that Bn ⊂ C. Now, for every pair of indices n, m for which it is possible, choose a Cn,m such that Bn ⊂ Cn,m ⊂ Bm . Obviously, it is a countable sub collection of C and we claim that it is als ...
Covering space
In mathematics, more specifically algebraic topology, a covering map (also covering projection) is a continuous function p from a topological space, C, to a topological space, X, such that each point in X has an open neighbourhood evenly covered by p (as shown in the image); the precise definition is given below. In this case, C is called a covering space and X the base space of the covering projection. The definition implies that every covering map is a local homeomorphism.Covering spaces play an important role in homotopy theory, harmonic analysis, Riemannian geometry and differential topology. In Riemannian geometry for example, ramification is a generalization of the notion of covering maps. Covering spaces are also deeply intertwined with the study of homotopy groups and, in particular, the fundamental group. An important application comes from the result that, if X is a ""sufficiently good"" topological space, there is a bijection between the collection of all isomorphism classes of connected coverings of X and the conjugacy classes of subgroups of the fundamental group of X.