In mathematics, specifically topology, a sequence covering map is any of a class of maps between topological spaces whose definitions all somehow relate sequences in the codomain with sequences in the domain. Examples include sequentially quotient maps, sequence coverings, 1-sequence coverings, and 2-sequence coverings. [1] [2] [3] [4] These classes of maps are closely related to sequential spaces. If the domain and/or codomain have certain additional topological properties (often, the spaces being Hausdorff and first-countable is more than enough) then these definitions become equivalent to other well-known classes of maps, such as open maps or quotient maps, for example. In these situations, characterizations of such properties in terms of convergent sequences might provide benefits similar to those provided by, say for instance, the characterization of continuity in terms of sequential continuity or the characterization of compactness in terms of sequential compactness (whenever such characterizations hold).
A subset of is said to be sequentially open in if whenever a sequence in converges (in ) to some point that belongs to then that sequence is necessarily eventually in (i.e. at most finitely many points in the sequence do not belong to ). The set of all sequentially open subsets of forms a topology on that is finer than 's given topology By definition, is called a sequential space if Given a sequence in and a point in if and only if in Moreover, is the finest topology on for which this characterization of sequence convergence in holds.
A map is called sequentially continuous if is continuous, which happens if and only if for every sequence in and every if in then necessarily in Every continuous map is sequentially continuous although in general, the converse may fail to hold. In fact, a space is a sequential space if and only if it has the following universal property for sequential spaces:
The sequential closure in of a subset is the set consisting of all for which there exists a sequence in that converges to in A subset is called sequentially closed in if which happens if and only if whenever a sequence in converges in to some point then necessarily The space is called a Fréchet–Urysohn space if for every subset which happens if and only if every subspace of is a sequential space. Every first-countable space is a Fréchet–Urysohn space and thus also a sequential space. All pseudometrizable spaces, metrizable spaces, and second-countable spaces are first-countable.
A sequence in a set is by definition a function whose value at is denoted by (although the usual notation used with functions, such as parentheses or composition might be used in certain situations to improve readability). Statements such as "the sequence is injective" or "the image (i.e. range) of a sequence is infinite" as well as other terminology and notation that is defined for functions can thus be applied to sequences. A sequence is said to be a subsequence of another sequence if there exists a strictly increasing map (possibly denoted by instead) such that for every where this condition can be expressed in terms of function composition as: As usual, if is declared to be (such as by definition) a subsequence of then it should immediately be assumed that is strictly increasing. The notation and mean that the sequence is valued in the set
The function is called a sequence covering if for every convergent sequence in there exists a sequence such that It is called a 1-sequence covering if for every there exists some such that every sequence that converges to in there exists a sequence such that and converges to in It is a 2-sequence covering if is surjective and also for every and every every sequence and converges to in there exists a sequence such that and converges to in A map is a compact covering if for every compact there exists some compact subset such that
In analogy with the definition of sequential continuity, a map is called a sequentially quotient map if
is a quotient map, [5] which happens if and only if for any subset is sequentially open if and only if this is true of in Sequentially quotient maps were introduced in Boone & Siwiec 1976 who defined them as above. [5]
Every sequentially quotient map is necessarily surjective and sequentially continuous although they may fail to be continuous. If is a sequentially continuous surjection whose domain is a sequential space, then is a quotient map if and only if is a sequential space and is a sequentially quotient map.
Call a space sequentially Hausdorff if is a Hausdorff space. [6] In an analogous manner, a "sequential version" of every other separation axiom can be defined in terms of whether or not the space possess it. Every Hausdorff space is necessarily sequentially Hausdorff. A sequential space is Hausdorff if and only if it is sequentially Hausdorff.
If is a sequentially continuous surjection then assuming that is sequentially Hausdorff, the following are equivalent:
If the assumption that is sequentially Hausdorff were to be removed, then statement (2) would still imply the other two statement but the above characterization would no longer be guaranteed to hold (however, if points in the codomain were required to be sequentially closed then any sequentially quotient map would necessarily satisfy condition (3)). This remains true even if the sequential continuity requirement on was strengthened to require (ordinary) continuity. Instead of using the original definition, some authors define "sequentially quotient map" to mean a continuous surjection that satisfies condition (2) or alternatively, condition (3). If the codomain is sequentially Hausdorff then these definitions differs from the original only in the added requirement of continuity (rather than merely requiring sequential continuity).
The map is called presequential if for every convergent sequence in such that is not eventually equal to the set is not sequentially closed in [5] where this set may also be described as:
Equivalently, is presequential if and only if for every convergent sequence in such that the set is not sequentially closed in
A surjective map between Hausdorff spaces is sequentially quotient if and only if it is sequentially continuous and a presequential map. [5]
If is a continuous surjection between two first-countable Hausdorff spaces then the following statements are true: [7] [8] [9] [10] [11] [12] [3] [4]
and if in addition both and are separable metric spaces then to this list may be appended:
The following is a sufficient condition for a continuous surjection to be sequentially open, which with additional assumptions, results in a characterization of open maps. Assume that is a continuous surjection from a regular space onto a Hausdorff space If the restriction is sequentially quotient for every open subset of then maps open subsets of to sequentially open subsets of Consequently, if and are also sequential spaces, then is an open map if and only if is sequentially quotient (or equivalently, quotient) for every open subset of
Given an element in the codomain of a (not necessarily surjective) continuous function the following gives a sufficient condition for to belong to 's image: A family of subsets of a topological space is said to be locally finite at a point if there exists some open neighborhood of such that the set is finite. Assume that is a continuous map between two Hausdorff first-countable spaces and let If there exists a sequence in such that (1) and (2) there exists some such that is not locally finite at then The converse is true if there is no point at which is locally constant; that is, if there does not exist any non-empty open subset of on which restricts to a constant map.
Suppose is a continuous open surjection from a first-countable space onto a Hausdorff space let be any non-empty subset, and let where denotes the closure of in Then given any and any sequence in that converges to there exists a sequence in that converges to as well as a subsequence of such that for all In short, this states that given a convergent sequence such that then for any other belonging to the same fiber as it is always possible to find a subsequence such that can be "lifted" by to a sequence that converges to
The following shows that under certain conditions, a map's fiber being a countable set is enough to guarantee the existence of a point of openness. If is a sequence covering from a Hausdorff sequential space onto a Hausdorff first-countable space and if is such that the fiber is a countable set, then there exists some such that is a point of openness for Consequently, if is quotient map between two Hausdorff first-countable spaces and if every fiber of is countable, then is an almost open map and consequently, also a 1-sequence covering.
This is a glossary of some terms used in the branch of mathematics known as topology. Although there is no absolute distinction between different areas of topology, the focus here is on general topology. The following definitions are also fundamental to algebraic topology, differential topology and geometric topology.
In mathematics, an open set is a generalization of an open interval in the real line.
In mathematics, a topological vector space is one of the basic structures investigated in functional analysis. A topological vector space is a vector space that is also a topological space with the property that the vector space operations are also continuous functions. Such a topology is called a vector topology and every topological vector space has a uniform topological structure, allowing a notion of uniform convergence and completeness. Some authors also require that the space is a Hausdorff space. One of the most widely studied categories of TVSs are locally convex topological vector spaces. This article focuses on TVSs that are not necessarily locally convex. Banach spaces, Hilbert spaces and Sobolev spaces are other well-known examples of TVSs.
In mathematics, a base (or basis; pl.: bases) for the topology τ of a topological space (X, τ) is a family of open subsets of X such that every open set of the topology is equal to the union of some sub-family of . For example, the set of all open intervals in the real number line is a basis for the Euclidean topology on because every open interval is an open set, and also every open subset of can be written as a union of some family of open intervals.
In mathematics, general topology is the branch of topology that deals with the basic set-theoretic definitions and constructions used in topology. It is the foundation of most other branches of topology, including differential topology, geometric topology, and algebraic topology.
In mathematics, more specifically in topology, an open map is a function between two topological spaces that maps open sets to open sets. That is, a function is open if for any open set in the image is open in Likewise, a closed map is a function that maps closed sets to closed sets. A map may be open, closed, both, or neither; in particular, an open map need not be closed and vice versa.
In functional analysis and related branches of mathematics, the Banach–Alaoglu theorem states that the closed unit ball of the dual space of a normed vector space is compact in the weak* topology. A common proof identifies the unit ball with the weak-* topology as a closed subset of a product of compact sets with the product topology. As a consequence of Tychonoff's theorem, this product, and hence the unit ball within, is compact.
In functional analysis and related areas of mathematics a polar topology, topology of -convergence or topology of uniform convergence on the sets of is a method to define locally convex topologies on the vector spaces of a pairing.
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In general topology and related areas of mathematics, the final topology on a set with respect to a family of functions from topological spaces into is the finest topology on that makes all those functions continuous.
In topology and related fields of mathematics, a sequential space is a topological space whose topology can be completely characterized by its convergent/divergent sequences. They can be thought of as spaces that satisfy a very weak axiom of countability, and all first-countable spaces are sequential.
In mathematics, lifting theory was first introduced by John von Neumann in a pioneering paper from 1931, in which he answered a question raised by Alfréd Haar. The theory was further developed by Dorothy Maharam (1958) and by Alexandra Ionescu Tulcea and Cassius Ionescu Tulcea (1961). Lifting theory was motivated to a large extent by its striking applications. Its development up to 1969 was described in a monograph of the Ionescu Tulceas. Lifting theory continued to develop since then, yielding new results and applications.
In the field of topology, a Fréchet–Urysohn space is a topological space with the property that for every subset the closure of in is identical to the sequential closure of in Fréchet–Urysohn spaces are a special type of sequential space.
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In functional analysis, a topological homomorphism or simply homomorphism is the analog of homomorphisms for the category of topological vector spaces (TVSs). This concept is of considerable importance in functional analysis and the famous open mapping theorem gives a sufficient condition for a continuous linear map between Fréchet spaces to be a topological homomorphism.
In functional analysis and related areas of mathematics, a metrizable topological vector space (TVS) is a TVS whose topology is induced by a metric. An LM-space is an inductive limit of a sequence of locally convex metrizable TVS.
In mathematics, particularly in functional analysis and topology, the closed graph theorem is a result connecting the continuity of certain kinds of functions to a topological property of their graph. In its most elementary form, the closed graph theorem states that a linear function between two Banach spaces is continuous if and only if the graph of that function is closed.