CategoricalSequence

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categorical sequence

(Definition)

Definition 0.1 A categorical sequence is a linear `diagram' of morphisms, or arrows, in an abstract category. In a concrete category, such as the category of sets, the categorical sequence consists of sets joined by set-theoretical mappings in linear fashion, such as:

$\displaystyle \cdots \rightarrow A\buildrel f \over \longrightarrow B \buildrel \phi \over \longrightarrow Hom_{Set}(A,B),$

where $Hom_{Set}(A,B)$ is the set of functions from set $A$ to set $B$ .

Examples

The chain complex is a categorical sequence example:

Consider a ring $R$ and the chain complex consisting of a sequence of $R$ -modules and homomorphisms:

$\displaystyle \cdots \rightarrow A_{n+1} \buildrel {d_{n+1}} \over \longrightarrow A_n \buildrel {d_n} \over \longrightarrow A_{n-1} \rightarrow \cdots$

(with the additional condition imposed by $d_n\circ d_{n+1} = 0$ for each pair of adjacent homomorphisms $(d_{n+1}, d_n)$ ; this is equivalent to the condition $\operatorname{im}d_{n+1} \subseteq \operatorname{ker}d_n$ that needs to be satisfied in order to define this categorical sequence completely as a chain complex). Furthermore, a sequence of homomorphisms

$\displaystyle \cdots \rightarrow A_{n+1} \buildrel {f_{n+1}} \over \longrightarrow A_n \buildrel {f_n} \over \longrightarrow A_{n-1} \rightarrow \cdots$

is said to be exact if each pair of adjacent homomorphisms $(f_{n+1}, f_n)$ is exact, that is, if ${\rm im} f_{n+1} = {\rm ker} f_n$ for all $n$

. This concept can be then generalized to morphisms in a categorical exact sequence, thus leading to the corresponding definition of an exact sequence in an abelian category.

Remark 0.1 Inasmuch as categorical diagrams can be defined as functors, exact sequences of special types of morphisms can also be regarded as the corresponding, special functors. Thus, exact sequences in Abelian categories can be regarded as certain functors of Abelian categories; the details of such functorial (abelian) constructions are left to the reader as an exercise. Moreover, in (commutative or Abelian) homological algebra, an exact functor is simply defined as a functor $F$

between two Abelian categories, $\mathcal{A}$ and $\mathcal{B}$ , $F: \mathcal{A} \to \mathcal{B}$ , which preserves categorical exact sequences, that is, if $F$

carries a short exact sequence $0 \to C \to D \to E \to 0$ (with $0, C, D$

and

objects in $\mathcal{A}$ ) into the corresponding sequence in the Abelian category $\mathcal{B}$ , ( $0 \to F(C) \to F(D) \to F(E) \to 0$ ), which is also exact (in $\mathcal{B}$ ).

"categorical sequence" is owned by bci1.

See Also: category

Other names:

homological sequence

Also defines:

homological sequence

Keywords:

categorical sequence, homological sequence

Cross-references: objects, types, functors, categorical diagrams, abelian category, concept, homomorphisms, functions, category, morphisms, diagram
There are 7 references to this object.

This is version 2 of categorical sequence, born on 2009-01-26, modified 2009-01-26.
Object id is 438, canonical name is CategoricalSequence.
Accessed 1021 times total.

Classification:

Physics Classification:	02. (Mathematical methods in physics)
	03. (Quantum mechanics, field theories, and special relativity )
	03.65.Fd (Algebraic methods )

Pending Errata and Addenda

None.

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