Commutative diagram
In mathematics, and especially in category theory, a commutative diagram is a diagram such that all directed paths in the diagram with the same start and endpoints lead to the same result. It is said that commutative diagrams play the role in category theory that equations play in algebra.
Description
A commutative diagram often consists of three parts:- objects
- morphisms
- paths or composites
Arrow symbols
- A monomorphism may be labeled with a or a.
- An epimorphism may be labeled with a.
- An isomorphism may be labeled with a.
- The dashed arrow typically represents the claim that the indicated morphism exists ; the arrow may be optionally labeled as.
- * If the morphism is in addition unique, then the dashed arrow may be labeled or.
- If the morphism acts between two arrows, it's called preferably a natural transformation and may be labelled as .
Verifying commutativity
Commutativity makes sense for a polygon of any finite number of sides, and a diagram is commutative if every polygonal subdiagram is commutative.Note that a diagram may be non-commutative, i.e., the composition of different paths in the diagram may not give the same result.
Examples
Example 1
In the left diagram, which expresses the first isomorphism theorem, commutativity of the triangle means that. In the right diagram, commutativity of the square means.Example 2
In order for the diagram below to commute, three equalities must be satisfied:Diagram chasing
Diagram chasing is a method of mathematical proof used especially in homological algebra, where one establishes a property of some morphism by tracing the elements of a commutative diagram. A proof by diagram chasing typically involves the formal use of the properties of the diagram, such as injective or surjective maps, or exact sequences. A syllogism is constructed, for which the graphical display of the diagram is just a visual aid. It follows that one ends up "chasing" elements around the diagram, until the desired element or result is constructed or verified.Examples of proofs by diagram chasing include those typically given for the five lemma, the snake lemma, the zig-zag lemma, and the nine lemma.
In higher category theory
In higher category theory, one considers not only objects and arrows, but arrows between the arrows, arrows between arrows between arrows, and so on ad infinitum. For example, the category of small categories Cat is naturally a 2-category, with functors as its arrows and natural transformations as the arrows between functors. In this setting, commutative diagrams may include these higher arrows as well, which are often depicted in the following style:. For example, the following diagram depicts two categories ' and ', together with two functors, : ' → ' and a natural transformation : ⇒ :There are two kinds of composition in a 2-category, and they may also be depicted via pasting diagrams.
Diagrams as functors
A commutative diagram in a category C can be interpreted as a functor from an index category J to C; one calls the functor a diagram.More formally, a commutative diagram is a visualization of a diagram indexed by a poset category. Such a diagram typically includes:
- a node for every object in the index category,
- an arrow for a generating set of morphisms,
- the commutativity of the diagram, corresponding to the uniqueness of a map between two objects in a poset category.
- the objects are the nodes,
- there is a morphism between any two objects if and only if there is a path between the nodes,
- with the relation that this morphism is unique.