Dagger category

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The dagger structure present in a dagger compact category (introduced in [1] by B. Coecke and S. Abramsky under the name strongly compact closed categories) has been extracted by Peter Selinger in [2]. This structure has its own importance since many categories can possess a dagger structure without being compact closed.

Contents

[edit] Formal definition

The following definition is taken from [2].

In mathematics, a dagger category is a category \mathbb{C} equipped with an involutive, identity-on-object functor

\dagger:\mathbb{C}^{op}\rightarrow\mathbb{C}.

which associates to every morphism f:A\rightarrow B in \mathbb{C} its adjoint f^\dagger:B\rightarrow A such that for all f:A\rightarrow B and g:B\rightarrow C,

  • id_A=id_A^\dagger:A\rightarrow A
  • (g\circ f)^\dagger=f^\dagger\circ g^\dagger:C\rightarrow A
  • f^{\dagger\dagger}=f:A\rightarrow B

Note that in the previous definition, the term adjoint is used in the linear-algebraic sense, not in the category theoretic sense.

[edit] Examples


[edit] Remarkable morphisms

In a dagger category \mathbb{C}, a morphism f is called

  • unitary if f^\dagger=f^{-1};
  • self-adjoint if f=f^\dagger.

The terms unitary and self-adjoint in the previous definition are taken from the category of Hilbert spaces where the morphisms satisfying those properties are then unitary and self-adjoint in the usual sense.

[edit] See also

[edit] References

[1] S. Abramsky and B. Coecke, A categorical semantics of quantum protocols, Proceedings of the 19th IEEE conference on Logic in Computer Science (LiCS'04). IEEE Computer Science Press (2004).

[2] 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.