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Γ ∞ = { (r, ∞) : r ∈ } generates a topology that is strictly coarser than both the Euclidean topology and the topology generated by Σ ∞. The sets Σ ∞ and Γ ∞ are disjoint, but nevertheless Γ ∞ is a subset of the topology generated by Σ ∞.
There are many ways to define a topology on R, the set of real numbers. The standard topology on R is generated by the open intervals. The set of all open intervals forms a base or basis for the topology, meaning that every open set is a union of some collection of sets from the base. In particular, this means that a set is open if there exists ...
The pseudometric topology is the topology generated by the open balls = {: (,) <}, which form a basis for the topology. [3] A topological space is said to be a pseudometrizable space [ 4 ] if the space can be given a pseudometric such that the pseudometric topology coincides with the given topology on the space.
It is the topology generated by the basis of all half-open intervals [a,b), where a and b are real numbers. The resulting topological space is called the Sorgenfrey line after Robert Sorgenfrey or the arrow and is sometimes written R l {\displaystyle \mathbb {R} _{l}} .
In any metric space, the open balls form a base for a topology on that space. [1] The Euclidean topology on R n {\displaystyle \mathbb {R} ^{n}} is the topology generated by these balls.
The Database of Original & Non-Theoretical Uses of Topology (DONUT) is a database of scholarly articles featuring practical applications of topological data analysis to various areas of science. DONUT was started in 2017 by Barbara Giunti, Janis Lazovskis, and Bastian Rieck, [ 126 ] and as of October 2023 currently contains 447 articles. [ 127 ]
The finest topology on X is the discrete topology; this topology makes all subsets open. The coarsest topology on X is the trivial topology; this topology only admits the empty set and the whole space as open sets. In function spaces and spaces of measures there are often a number of possible topologies.
Thus, we can start with a fixed topology and find subbases for that topology, and we can also start with an arbitrary subcollection of the power set ℘ and form the topology generated by that subcollection. We can freely use either equivalent definition above; indeed, in many cases, one of the two conditions is more useful than the other.