Chain homotopy: Difference between revisions

Latest revision as of 19:40, 11 May 2008

Definition

Given two chain complexes $A$ and $B$ , and chain maps $f,g:A\to B$ , an algebraic homotopy or chain homotopy between $f$ and $g$ is an expression of $f-g$ as $dk+kd$ where $k$ is a collection of homomorphisms from $A_{n}$ to $B_{n+1}$ for every $n$ .

Equivalently, two homomorphisms between chain complexes are in algebraic homotopy if they lie in the same coset of the group of homomorphisms of the form $dk+kd$ .

If a chain homotopy exists between $f$ and $g$ we say that $f,g$ are chain-homotopic chain maps.

Facts

If $f$ and $g$ are two homotopic maps between topological spaces, then the induced maps between the singular complexes are in algebraic homotopy. For full proof, refer: Homotopy of maps induces chain homotopy

@@ Line 8: / Line 8: @@
 If a chain homotopy exists between <math>f</math> and <math>g</math> we say that <math>f,g</math> are [[chain-homotopic chain maps]].
-==Relation with other properties==
-* [[Homology isomorphism]] (also called quasi-isomorphism or quism)
 ==Facts==
 If <math>f</math> and <math>g</math> are two homotopic maps between topological spaces, then the induced maps between the singular complexes are in algebraic homotopy. {{proofat|[[Homotopy of maps induces chain homotopy]]}}