End (topology) explained

In topology, a branch of mathematics, the ends of a topological space are, roughly speaking, the connected components of the "ideal boundary" of the space. That is, each end represents a topologically distinct way to move to infinity within the space. Adding a point at each end yields a compactification of the original space, known as the end compactification.

The notion of an end of a topological space was introduced by .

Definition

Let

be a topological space, and suppose thatis an ascending sequence of compact subsets of

whose interiors cover

. Then

has one end for every sequencewhere each

U_n

is a connected component of

X\setminusK_n

. The number of ends does not depend on the specific sequence

(K_i)

of compact sets; there is a natural bijection between the sets of ends associated with any two such sequences.

Using this definition, a neighborhood of an end

(U_i)

is an open set

such that

V\supsetU_n

for some

. Such neighborhoods represent the neighborhoods of the corresponding point at infinity in the end compactification (this "compactification" is not always compact; the topological space X has to be connected and locally connected).

The definition of ends given above applies only to spaces

that possess an exhaustion by compact sets (that is,

must be hemicompact). However, it can be generalized as follows: let

be any topological space, and consider the direct system

\{K\}

of compact subsets of

and inclusion maps. There is a corresponding inverse system

\{\pi_0(X\setminusK)\}

, where

\pi_0(Y)

denotes the set of connected components of a space

, and each inclusion map

Y\toZ

induces a function

\pi_0(Y)\to\pi_0(Z)

. Then set of ends of

is defined to be the inverse limit of this inverse system.

Under this definition, the set of ends is a functor from the category of topological spaces, where morphisms are only proper continuous maps, to the category of sets. Explicitly, if

\varphi:X\toY

is a proper map and

x=(x_K)_K

is an end of

(i.e. each element

x_K

in the family is a connected component of

X\setminusK

and they are compatible with maps induced by inclusions) then

\varphi(x)

is the family

\varphi_*(x


	\varphi^-1(K')

)

where

ranges over compact subsets of Y and

\varphi_*

is the map induced by

\varphi

from

\pi_0(X\setminus\varphi^-1(K'))

\pi_0(Y\setminusK')

. Properness of

\varphi

is used to ensure that each

\varphi^-1(K)

is compact in

The original definition above represents the special case where the direct system of compact subsets has a cofinal sequence.

Examples

The set of ends of any compact space is the empty set.

has two ends. For example, if we let K_n be the closed interval [−''n'', ''n''], then the two ends are the sequences of open sets U_n = (n, ∞) and V_n = (-∞, -n). These ends are usually referred to as "infinity" and "minus infinity", respectively.

If n > 1, then Euclidean space

Rⁿ

has only one end. This is because

Rⁿ\smallsetminusK

has only one unbounded component for any compact set K.

More generally, if M is a compact manifold with boundary, then the number of ends of the interior of M is equal to the number of connected components of the boundary of M.
The union of n distinct rays emanating from the origin in

R²

has n ends.

The infinite complete binary tree has uncountably many ends, corresponding to the uncountably many different descending paths starting at the root. (This can be seen by letting K_n be the complete binary tree of depth n.) These ends can be thought of as the "leaves" of the infinite tree. In the end compactification, the set of ends has the topology of a Cantor set.

Ends of graphs and groups

See main article: article and End (graph theory). In infinite graph theory, an end is defined slightly differently, as an equivalence class of semi-infinite paths in the graph, or as a haven, a function mapping finite sets of vertices to connected components of their complements. However, for locally finite graphs (graphs in which each vertex has finite degree), the ends defined in this way correspond one-for-one with the ends of topological spaces defined from the graph .

The ends of a finitely generated group are defined to be the ends of the corresponding Cayley graph; this definition is insensitive to the choice of generating set. Every finitely-generated infinite group has either 1, 2, or infinitely many ends, and Stallings theorem about ends of groups provides a decomposition for groups with more than one end.

Ends of a CW complex

For a path connected CW-complex, the ends can be characterized as homotopy classes of proper maps

R^+\toX

, called rays in X: more precisely, if between the restriction —to the subset

— of any two of these maps exists a proper homotopy we say that they are equivalent and they define an equivalence class of proper rays. This set is called an end of X.

References

.
- Ross Geoghegan, Topological methods in group theory, GTM-243 (2008), Springer .
Book: 10.1017/CBO9781107325449.007. Topological methods in group theory. Homological Group Theory. 137–204. 1979. Scott. Peter. Wall. Terry. Wall. C. T. C.. 9781107325449.