In mathematics, the fiber (US English) or fibre (British English) of an element under a function is the preimage of the singleton set ,[1]: p.69 that is
This set is often denoted as , even though this notation is inappropriate since the inverse relation of is not necessarily a function.
Properties and applications
In naive set theory
If and are the domain and image of , respectively, then the fibers of are the sets in
which is a partition of the domain set . Note that must be restricted to the image set of , since otherwise would be the empty set which is not allowed in a partition. The fiber containing an element is the set
For example, let be the function from to that sends point to . The fiber of 5 under are all the points on the straight line with equation . The fibers of are that line and all the straight lines parallel to it, which form a partition of the plane .
More generally, if is a linear map from some linear vector space to some other linear space , the fibers of are affine subspaces of , which are all the translated copies of the null space of .
If is a real-valued function of several real variables, the fibers of the function are the level sets of . If is also a continuous function and is in the image of the level set will typically be a curve in 2D, a surface in 3D, and, more generally, a hypersurface in the domain of
The fibers of are the equivalence classes of the equivalence relation defined on the domain such that if and only if .
In topology
In point set topology, one generally considers functions from topological spaces to topological spaces.
If is a continuous function and if (or more generally, the image set ) is a T1 space then every fiber is a closed subset of In particular, if is a local homeomorphism from to , each fiber of is a discrete subspace of .
A function between topological spaces is called monotone if every fiber is a connected subspace of its domain. A function is monotone in this topological sense if and only if it is non-increasing or non-decreasing, which is the usual meaning of "monotone function" in real analysis.
A function between topological spaces is (sometimes) called a proper map if every fiber is a compact subspace of its domain. However, many authors use other non-equivalent competing definitions of "proper map" so it is advisable to always check how a particular author defines this term. A continuous closed surjective function whose fibers are all compact is called a perfect map.
A fiber bundle is a function between topological spaces and whose fibers have certain special properties related to the topology of those spaces.
In algebraic geometry
In algebraic geometry, if is a morphism of schemes, the fiber of a point in is the fiber product of schemes
where is the residue field at
See also
References
- ↑ Lee, John M. (2011). Introduction to Topological Manifolds (2nd ed.). Springer Verlag. ISBN 978-1-4419-7940-7.