Opposite category: Difference between revisions
Appearance
Content deleted Content added
Tag: references removed |
|||
Line 15: | Line 15: | ||
* The [[Pontryagin duality]] restricts to an equivalence between the category of [[Compact_space#Definitions|compact]] [[Hausdorff space|Hausdorff]] [[abelian group|abelian]] [[topological group]]s and the opposite of the category of (discrete) abelian groups. |
* The [[Pontryagin duality]] restricts to an equivalence between the category of [[Compact_space#Definitions|compact]] [[Hausdorff space|Hausdorff]] [[abelian group|abelian]] [[topological group]]s and the opposite of the category of (discrete) abelian groups. |
||
* By the Gelfand-Neumark theorem, the category of localizable [[Sigma-algebra|measurable spaces]] (with [[measurable function|measurable maps]]) is equivalent to the category of commutative [[Von Neumann algebra|Von Neumann algebras]] (with [[Normal_operator|normal]] [[Unital map|unital]] homomorphisms of *-algebras). <ref name=MO1>{{cite web|url=http://mathoverflow.net/questions/20740/is-there-an-introduction-to-probability-theory-from-a-structuralist-categorical-p|title=Is there an introduction to probability theory from a structuralist/categorical perspective? |
* By the Gelfand-Neumark theorem, the category of localizable [[Sigma-algebra|measurable spaces]] (with [[measurable function|measurable maps]]) is equivalent to the category of commutative [[Von Neumann algebra|Von Neumann algebras]] (with [[Normal_operator|normal]] [[Unital map|unital]] homomorphisms of *-algebras). <ref name=MO1>{{cite web|url=http://mathoverflow.net/questions/20740/is-there-an-introduction-to-probability-theory-from-a-structuralist-categorical-p|title=Is there an introduction to probability theory from a structuralist/categorical perspective?|publisher=MathOverflow|accessdate=25 October 2010}}</ref> |
||
==Properties== |
==Properties== |
Revision as of 14:11, 26 October 2010
In category theory, a branch of mathematics, the opposite category or dual category Cop of a given category C is formed by reversing the morphisms, i.e. interchanging the source and target of each morphism. Doing the reversal twice yields the original category, so the opposite of an opposite category is the original category itself. In symbols, .
Examples
- An example comes from reversing the direction of inequalities in a partial order. So if X is a set and ≤ a partial order relation, we can define a new partial order relation ≤new by
- x ≤new y if and only if y ≤ x.
- For example, there are opposite pairs child/parent, or descendant/ancestor.
- The category of Boolean algebras and Boolean homomorphisms is equivalent to the opposite of the category of Stone spaces and continuous functions.
- The category of affine schemes is equivalent to the opposite of the category of commutative rings.
- The Pontryagin duality restricts to an equivalence between the category of compact Hausdorff abelian topological groups and the opposite of the category of (discrete) abelian groups.
- By the Gelfand-Neumark theorem, the category of localizable measurable spaces (with measurable maps) is equivalent to the category of commutative Von Neumann algebras (with normal unital homomorphisms of *-algebras). [1]
Properties
(see product category)
(see functor category) [citation needed]
See also
- Citations
- ^ "Is there an introduction to probability theory from a structuralist/categorical perspective?". MathOverflow. Retrieved 25 October 2010.