Commutative diagram
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- For help on drawing commutative diagrams on Wikipedia, see meta:Help:Displaying a formula#Commutative_diagrams.
In mathematics, especially the many applications of category theory, a commutative diagram is a diagram of objects and morphisms such that, when picking two objects, one can follow any directed path through the diagram and obtain the same result by composition. Commutative diagrams play the role in category theory that equations play in algebra.
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[edit] Examples
The first isomorphism theorem is a commutative triangle as follows:
Since 
, the left diagram is commutative; and since 
, so is the right diagram.
Similarly, the square above is commutative if 
.
[edit] Symbols
In algebra texts, the type of morphism can be denoted with different arrow usages: monomorphisms with a 
, epimorphisms as a 
, and isomorphisms as a 
. This is common enough that texts often do not footnote explanations for the different arrows.
[edit] Verifying commutativity
Commutativity makes sense for a polygon of any finite number of sides (including just 1 or 2), and a diagram is commutative if every polygonal subdiagram is commutative.
[edit] Diagram chasing
Diagram chasing is a method of mathematical proof used especially in homological algebra. Given a commutative diagram, a proof by diagram chasing involves formally using 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. 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.
