Mapping cone

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In mathematics, especially homotopy theory, the mapping cone is a construction C_f of topology.

Given a map , the mapping cone C_f is defined to be the quotient topological space of with respect to the equivalence relation (x,0)˜(x',0), (x,1)˜f(x) (). Here I denotes the unit interval [0,1] with its standard topology.

If X is the circle S¹, C_f can be considered as the quotient space of the disjoint union of Y with the disk D² formed by identifying a point x on the boundary of D² to the point f(x) in Y.

Consider, for example, the case where Y is the circle, and

f: S¹ → Y = S¹

the identity function. Then the mapping cone C_f is homeomorphic to two disks joined on their boundary, which is topologically the sphere S².

The mapping cone is a special case of the double mapping cylinder. This is basically a cylinder joined on one end to a space X₁ via the map

f₁: S¹ → X₁

and joined on the other end to a space X₂ via the map

f₂: S¹ → X₂.

The mapping cone is the degenerate case of the double mapping cylinder, in which one space is a single point.

Given a space X and a loop

α: S¹ → X

representing an element of the fundamental group of X, we can form the mapping cone C_α. The effect of this is to make the loop α contractible in C_α, and therefore the equivalence class of α in the fundamental group of C_α will be simply the identity element.

[edit] Algebraic analogue

An algebraic manifestation of this construction appears on the chain complex level. In abstract terms this is an important part of the theory of triangulated categories.