Homotopy lifting property
In mathematics, in particular in homotopy theory within algebraic topology, the homotopy lifting property (also known as an instance of the right lifting property or the covering homotopy axiom) is a technical condition on a continuous function from a topological space E to another one, B.
It is designed to support the picture of E "above" B by allowing a homotopy taking place in B to be moved "upstairs" to E. For example, a covering map has a property of unique local lifting of paths to a given sheet; the uniqueness is because the fibers of a covering map are discrete spaces.
The homotopy lifting property will hold in many situations, such as the projection in a vector bundle, fiber bundle or fibration, where there need be no unique way of lifting.
Assume all maps are continuous functions between topological spaces.
has the homotopy lifting property,[1][2] or that
has the homotopy lifting property with respect to
, if: there exists a homotopy
The following diagram depicts this situation: The outer square (without the dotted arrow) commutes if and only if the hypotheses of the lifting property are true.
corresponds to a dotted arrow making the diagram commute.
This diagram is dual to that of the homotopy extension property; this duality is loosely referred to as Eckmann–Hilton duality.
satisfies the homotopy lifting property with respect to all spaces
is called a fibration, or one sometimes simply says that
has the homotopy lifting property.
A weaker notion of fibration is Serre fibration, for which homotopy lifting is only required for all CW complexes
There is a common generalization of the homotopy lifting property and the homotopy extension property.
Given a pair of spaces
Given additionally a map
has the homotopy lifting extension property if: The homotopy lifting property of
is obtained by taking
The homotopy extension property of
is obtained by taking
to be a constant map, so that
is irrelevant in that every map to E is trivially the lift of a constant map to the image point of
