Inclusion map

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In mathematics, if ${\displaystyle A}$ is a subset of ${\displaystyle B}$, then the inclusion map (also inclusion function, or canonical injection) is the function ${\displaystyle i}$ that sends each element, ${\displaystyle x}$ of ${\displaystyle A}$ to ${\displaystyle x}$, treated as an element of ${\displaystyle B}$:

${\displaystyle i:A\rightarrow B,\qquad i(x)=x.}$

A "hooked arrow" ${\displaystyle \hookrightarrow }$ is sometimes used in place of the function arrow above to denote an inclusion map.

This and other analogous injective functions ^[1] from substructures are sometimes called natural injections.

Given any morphism between objects X and Y, if there is an inclusion map into the domain ${\displaystyle i:A\rightarrow X}$, then one can form the restriction fi of f. In many instances, one can also construct a canonical inclusion into the codomain R→Y known as the range of f.

Inclusion maps tend to be homomorphisms of algebraic structures; thus, such inclusion maps are embeddings. More precisely, given a sub-structure closed under some operations, the inclusion map will be an embedding for tautological reasons, given the very definition by restriction of what one checks. For example, for a binary operation ${\displaystyle \star }$, to require that

${\displaystyle i(x\star y)=i(x)\star i(y)}$

is simply to say that ${\displaystyle \star }$ is consistently computed in the sub-structure and the large structure. The case of a unary operation is similar; but one should also look at nullary operations, which pick out a constant element. Here the point is that closure means such constants must already be given in the substructure.

Inclusion maps are seen in algebraic topology where if A is a strong deformation retract of X, the inclusion map yields an isomorphism between all homotopy groups (i.e. is a homotopy equivalence)

Inclusion maps in geometry come in different kinds: for example embeddings of submanifolds. Contravariant objects such as differential forms restrict to submanifolds, giving a mapping in the other direction. Another example, more sophisticated, is that of affine schemes, for which the inclusions

Spec(R/I) → Spec(R)

and

Spec(R/I²) → Spec(R)

may be different morphisms, where R is a commutative ring and I an ideal.

• Identity function

• Chevalley, C. (1956), Fundamental Concepts of Algebra, Academic Press, New York, ISBN 0121720500.