Dagger category: Difference between revisions
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A '''dagger symmetric monoidal category''' is a [[monoidal category]] <math>\langle\mathbb{C},\otimes, I\rangle</math> which also possesses a [[dagger category|dagger structure]]; in other words, it means that this category comes equipped not only with a [[monoidal category|tensor]] in the [[category theory|category theoretic]] sense but also with [[dagger category|dagger structure]] which is used to describe [[unitary operator|unitary morphism]] and [[self-adjoint|self-adjoint morphisms]] in <math>\mathbb{C}</math> that is, a form of abstract analogues of those found in '''FdHilb''', the [[category of finite dimensional Hilbert spaces]]. This type of [[category (mathematics)|category]] was introduced by Selinger<ref>P. Selinger, ''[http://www.mscs.dal.ca/~selinger/papers.html#dagger Dagger compact closed categories and completely positive maps]'', Proceedings of the 3rd International Workshop on Quantum Programming Languages, Chicago, June 30 - July 1, 2005.</ref> as an intermediate structure between [[dagger category|dagger categories]] and the [[dagger compact category|dagger compact categories]] that are used in [[categorical quantum mechanics]], an area which now also considers dagger symmetric monoidal categories when dealing with infinite dimensional [[quantum mechanical]] concepts. | |||
==Formal definition== | |||
A '''dagger symmetric monoidal category''' is a [[symmetric monoidal category]] <math>\mathbb{C}</math> which also has a [[dagger category|dagger structure]] such that for all <math>f:A\rightarrow B </math>, <math>g:C\rightarrow D </math> and all <math> A,B</math> and <math> C</math> in <math>Ob(\mathbb{C})</math>, | |||
*<math> (f\otimes g)^\dagger=f^\dagger\otimes g^\dagger:B\otimes D\rightarrow A\otimes C </math>; | |||
*<math> \alpha^\dagger_{A,B,C}=\alpha^{-1}_{A,B,C}:(A\otimes B)\otimes C\rightarrow A\otimes (B\otimes C)</math>; | |||
*<math> \rho^\dagger_A=\rho^{-1}_A:A \rightarrow A \otimes I</math>; | |||
*<math> \lambda^\dagger_A=\lambda^{-1}_A: A \rightarrow I \otimes A</math> and | |||
*<math> \sigma^\dagger_{A,B}=\sigma^{-1}_{A,B}:B \otimes A \rightarrow A \otimes B</math>. | |||
Here, <math>\alpha,\lambda,\rho</math> and <math>\sigma</math> are the [[natural isomorphism]]s that form the [[symmetric monoidal category|symmetric monoidal structure]]. | |||
==Examples== | |||
The following [[category (mathematics)|categories]] are examples of dagger symmetric monoidal categories: | |||
* The [[category (mathematics)|category]] '''Rel''' of [[Category of relations|sets and relations]] where the tensor is given by the [[Product (category theory)|product]] and where the dagger of a relation is given by its relational converse. | |||
* The [[category (mathematics)|category]] '''FdHilb''' of [[Category of finite dimensional Hilbert spaces|finite dimensional Hilbert spaces]] is a dagger symmetric monoidal category where the tensor is the usual [[tensor product]] of Hilbert spaces and where the dagger of a [[linear map]] is given by its [[hermitian adjoint]]. | |||
A dagger-symmetric category which is also [[compact closed category|compact closed]] is a [[dagger compact category]]; both of the above examples are in fact dagger compact. | |||
==See also== | |||
* [[Strongly ribbon category]] | |||
==References== | |||
{{Reflist}} | |||
[[Category:Dagger categories]] | |||
[[Category:Monoidal categories]] |
Revision as of 00:55, 15 March 2013
A dagger symmetric monoidal category is a monoidal category which also possesses a dagger structure; in other words, it means that this category comes equipped not only with a tensor in the category theoretic sense but also with dagger structure which is used to describe unitary morphism and self-adjoint morphisms in that is, a form of abstract analogues of those found in FdHilb, the category of finite dimensional Hilbert spaces. This type of category was introduced by Selinger[1] as an intermediate structure between dagger categories and the dagger compact categories that are used in categorical quantum mechanics, an area which now also considers dagger symmetric monoidal categories when dealing with infinite dimensional quantum mechanical concepts.
Formal definition
A dagger symmetric monoidal category is a symmetric monoidal category which also has a dagger structure such that for all , and all and in ,
Here, and are the natural isomorphisms that form the symmetric monoidal structure.
Examples
The following categories are examples of dagger symmetric monoidal categories:
- The category Rel of sets and relations where the tensor is given by the product and where the dagger of a relation is given by its relational converse.
- The category FdHilb of finite dimensional Hilbert spaces is a dagger symmetric monoidal category where the tensor is the usual tensor product of Hilbert spaces and where the dagger of a linear map is given by its hermitian adjoint.
A dagger-symmetric category which is also compact closed is a dagger compact category; both of the above examples are in fact dagger compact.
See also
References
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- ↑ P. Selinger, Dagger compact closed categories and completely positive maps, Proceedings of the 3rd International Workshop on Quantum Programming Languages, Chicago, June 30 - July 1, 2005.