Category theory

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Category theory

A natural language has nouns and verbs. High school mathematics introduces sets and functions acting on them. A computer program can act upon an entity of information, producing another entity. A vector can be subjected to a linear transformation. From observations such as these, two mathematical concepts are distilled: the object and the map or morphism.

Definition

A category consists of the following data:

1. A class of "objects," denoted ${\displaystyle ob(C)}$
2. For objects ${\displaystyle A,B,C\in ob(C)}$, a set ${\displaystyle {\text{Mor}}_{C}(A,B)}$ such that ${\displaystyle {\text{Mor}}_{C}(A,B)\cap {\text{Mor}}_{C}(A',B')}$ is empty if ${\displaystyle A\neq A'}$ and ${\displaystyle B\neq B'}$

together with a "law of composition": ${\displaystyle \circ :{\text{Mor}}_{C}(B,C)\times {\text{Mor}}_{C}(A,B)\to {\text{Mor}}_{C}(A,C)}$ (which we denote by ${\displaystyle (g,f)\mapsto g\circ f}$) having the following properties:

1. 1. Associativity: ${\displaystyle (h\circ g)\circ f=h\circ (g\circ f)}$ whenever the compositions are defined
   2. Identity: for every object ${\displaystyle A\in ob(C)}$ there is an element ${\displaystyle id_{A}}$ such that for all ${\displaystyle f\in {\text{Mor}}_{C}(A,B)}$, ${\displaystyle id_{B}\circ f=f}$ and ${\displaystyle f\circ id_{A}=f}$.

Examples

1. The category of sets:
2. The category of topological spaces:
3. The category of functors: if ${\displaystyle C}$ and ${\displaystyle D}$ are two categories, then there is a category consisting of all contravarient functors from ${\displaystyle C}$ to ${\displaystyle D}$, where morphisms are natural transformations.
4. The category of schemes is one of the principal objects of study