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In mathematics, particularly in the subfields of set theory and topology, a set is said to be saturated with respect to a function if is a subset of 's domain and if whenever sends two points and to the same value then belongs to (that is, if then ). Said more succinctly, the set is called saturated if

In topology, a subset of a topological space is saturated if it is equal to an intersection of open subsets of In a T1 space every set is saturated.

Definition

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Preliminaries

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Let   be a map. Given any subset   define its image under   to be the set:   and define its preimage or inverse image under   to be the set:  

Given   the fiber of   over   is defined to be the preimage:  

Any preimage of a single point in  's codomain   is referred to as a fiber of  

Saturated sets

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A set   is called  -saturated and is said to be saturated with respect to   if   is a subset of  's domain   and if any of the following equivalent conditions are satisfied:[1]

  1.  
  2. There exists a set   such that  
    • Any such set   necessarily contains   as a subset and moreover, it will also necessarily satisfy the equality   where   denotes the image of  
  3. If   and   satisfy   then  
  4. If   is such that the fiber   intersects   (that is, if  ), then this entire fiber is necessarily a subset of   (that is,  ).
  5. For every   the intersection   is equal to the empty set   or to  

Related to computability theory, this notion can be extended to programs. Here, considering a subset  , this can be considered saturated (or extensional) if  . In words, given two programs, if the first program is in the set of programs satisfying the property and two programs are computing the same thing, then also the second program satisfies the property. This means that if one program with a certain property is in the set, all programs computing the same function must also be in the set).

In this context, this notion can extend Rice's theorem, stating that:

Let   be a subset such that  . If   is saturated, then   is not recursive.

Examples

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Let   be any function. If   is any set then its preimage   under   is necessarily an  -saturated set. In particular, every fiber of a map   is an  -saturated set.

The empty set   and the domain   are always saturated. Arbitrary unions of saturated sets are saturated, as are arbitrary intersections of saturated sets.

Properties

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Let   and   be any sets and let   be any function.

If   or   is  -saturated then  

If   is  -saturated then   where note, in particular, that no requirements or conditions were placed on the set  

If   is a topology on   and   is any map then set   of all   that are saturated subsets of   forms a topology on   If   is also a topological space then   is continuous (respectively, a quotient map) if and only if the same is true of  

See also

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References

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  1. ^ Monk 1969, pp. 24–54.
  • G. Gierz; K. H. Hofmann; K. Keimel; J. D. Lawson; M. Mislove & D. S. Scott (2003). "Continuous Lattices and Domains". Encyclopedia of Mathematics and its Applications. Vol. 93. Cambridge University Press. ISBN 0-521-80338-1.
  • Monk, James Donald (1969). Introduction to Set Theory (PDF). International series in pure and applied mathematics. New York: McGraw-Hill. ISBN 978-0-07-042715-0. OCLC 1102.
  • Munkres, James R. (2000). Topology (Second ed.). Upper Saddle River, NJ: Prentice Hall, Inc. ISBN 978-0-13-181629-9. OCLC 42683260.