analysis (differential/integral calculus, functional analysis, topology)
metric space, normed vector space
open ball, open subset, neighbourhood
convergence, limit of a sequence
compactness, sequential compactness
continuous metric space valued function on compact metric space is uniformly continuous
…
…
topology (point-set topology, point-free topology)
see also differential topology, algebraic topology, functional analysis and topological homotopy theory
Basic concepts
fiber space, space attachment
Extra stuff, structure, properties
Kolmogorov space, Hausdorff space, regular space, normal space
sequentially compact, countably compact, locally compact, sigma-compact, paracompact, countably paracompact, strongly compact
Examples
Basic statements
closed subspaces of compact Hausdorff spaces are equivalently compact subspaces
open subspaces of compact Hausdorff spaces are locally compact
compact spaces equivalently have converging subnet of every net
continuous metric space valued function on compact metric space is uniformly continuous
paracompact Hausdorff spaces equivalently admit subordinate partitions of unity
injective proper maps to locally compact spaces are equivalently the closed embeddings
locally compact and second-countable spaces are sigma-compact
Theorems
Analysis Theorems
A convergence space is a generalisation of a topological space based on the concept of convergence of filters (or nets) as fundamental. The basic concepts of point-set topology (continuous functions, compact and Hausdorff topological spaces, etc) make sense also for convergence spaces, although not all theorems hold. The category of convergence spaces is a quasitopos and may be thought of as a nice category of spaces that includes Top as a full subcategory.
A convergence space is a set together with a relation from to , where is the set of filters on ; if , we say that converges to or that is a limit of . This must satisfy some axioms:
It follows that if and only if does. Given that, the convergence relation is defined precisely by specifying, for each point , a filter of subfilters? of the principal ultrafilter at . (But that is sort of a tongue twister.)
A filter clusters at a point , written , if there exists a proper filter such that and .
The definition can also be phrased in terms of nets; a net converges to if and only if its eventuality filter converges to .
The morphisms of convergence spaces are the continuous functions; a function between convergence spaces is continuous if implies that , where is the filter generated by the filterbase . In this way, convergence spaces form a concrete category .
Note that the definition of ‘convergence’ varies in the literature; at the extreme end, one could define it as any relation whatsoever from (or even from the class of all nets on , see generalised filter space) to , but that is so little structure as to be not very useful. An intermediate notion is that of filter space, in which (3) is not required, and that of preconvergence space, in which (1) and (3) are not required either. Here we follow the terminology of Lowen-Colebunders.
In measure theory, given a measure space and a measurable space , the space of almost-everywhere defined measurable functions from to becomes a convergence space under convergence almost everywhere?. In general, this convergence space does not fit into any of the examples below.
A pseudotopological space is a convergence space satisfying the star property:
Assuming the ultrafilter theorem (a weak version of the axiom of choice), it's enough to require that converges to whenever every ultrafilter that refines converges to (or clusters there, since these are equivalent for ultrafilters).
A subsequential space is a pseudotopological space that may be defined using only sequences instead of arbitrary nets/filters. (More precisely, a filter converges to only if it refines (the eventuality filter of) a sequence that converges to .)
A pretopological space is a convergence space that is infinitely filtered:
In particular, the intersection of all of the filters converging to (the neighbourhood filter of ) also converges to . Note that every pretopological space is pseudotopological.
Any topological space is a convergence space, and in fact a pretopological one: we define if every neighbourhood of belongs to . A convergence space is topological if it comes from a topology on . The full subcategory of consisting of the topological convergence spaces is equivalent to the category Top of topological spaces. In this way, the definitions below are all suggested by theorems about topological spaces.
Every Cauchy space is a convergence space.
The improper filter (the power set of ) converges to every point. On the other hand, a convergence space is Hausdorff if every proper filter converges to at most one point; then we have a partial function from the proper filters on to . A topological space is Hausdorff in the usual sense if and only if it is Hausdorff as a convergence space.
A convergence space is compact if every proper filter clusters at some point; that is, every proper filter is contained in a convergent proper filter. Equivalently (assuming the ultrafilter theorem), is compact iff every ultrafilter converges. A topological space is compact in the usual sense if and only if it is compact as a convergence space.
The topological convergence spaces can be characterized as the pseudotopological ones in which the convergence satisfies a certain “associativity” condition. In this way one can (assuming the ultrafilter theorem) think of a topological space as a “generalized multicategory” parametrized by ultrafilters. In particular, note that a compact Hausdorff pseudotopological space is defined by a single function , where is the set of ultrafilters on , such that the composite is the identity. That is, it is an algebra for the pointed endofunctor . The compact Hausdorff topological spaces (the compacta) are precisely the algebras for considered as a monad. If we treat as a monad on Rel, then the lax algebras are the topological spaces in their guise as relational beta-modules.
Given a convergence space, a filter star-converges to a point , written , if every proper filter that refines clusters at . (Assuming the ultrafilter theorem, star-converges to iff every ultrafilter that refines converges to .) The relation of star convergence makes any convergence space into a pseudotopological space with a weaker convergence. In this way, becomes a reflective subcategory of over .
Note: the term ‘star convergence’ and its symbol ‘’ are my own, formed from ‘star property’ above, which I got from HAF. Other possibilities that I can think of: ‘ultraconvergence’, ‘universal convergence’, ‘subconvergence’. —Toby
Given a convergence space, a set is a neighbourhood of a point , written , if belongs to every filter that converges to ; it follows that belongs to every filter that star-converges to . The relation of being a neighbourhood makes any convergence space into a pretopological space, although the pretopological convergence is weaker in general. In this way, is a reflective subcategory of (and in fact of ) over .
Other pretopological notions: The preinterior of a set is the set of all points such that . The preclosure of is the set of all points such that every neighbourhood of meets (has inhabited intersection with) . For more on these, see pretopological space.
Given a convergence space, a set is open if belongs to every filter that converges to any point in , or equivalently if belongs to every filter that star-converges to any point in , or equivalently if equals its preinterior. The class of open sets makes any convergence space into a topological space, although the topological convergence is weaker in general. In this way, is a reflective subcategory of (and in fact of and ) over .
Other topological notions: A set is closed if meets every neighbourhood of every point that belongs to , equivalently if equals its preclosure. The interior of is the union of all of the open sets contained in ; it is the largest open set contained in . The closure of is the intersection of all of the closed sets that contain ; it is the smallest closed set that contains . (For a topological convergence space, the interior and closure match the preinterior and preclosure.)
The inclusions are all inclusions of full subcategories over . That is, they all agree on what a continuous function is.
The only hard part is proving that, if whenever in a pretopological space, then whenever . This is usually proved by contradiction and flagrant use of choice: supposing that but , then every neighbourhood of must satisfy , so choose for each such a point such that but , defining a net (indexed by neighbourhoods of ordered by reverse inclusion), such that , but , so , getting a contradiction.
But the theorem is in fact perfectly constructive: the filter of neighbourhoods of converges to , so ; all that really matters is that , so that for each and , for some with , , so , making a neighbourhood of .
Last revised on November 18, 2024 at 13:40:12. See the history of this page for a list of all contributions to it.