Formations and chain complexes II (Ex)

From Manifold Atlas

(Difference between revisions)

Jump to: navigation, search

Latest revision as of 16:20, 31 May 2012

An n-dimensional $<wikitex>; {{beginthm|Definition|{{cite|Ranicki1980|Proposition 4.6}} }} An n-dimensional $\epsilon$-symmetric($\epsilon$-quadratic) complex $(C, \phi)$ ($(C, \psi)$) is called ''well-connected'' if $H_0(C)= 0$. {{endthm}} {{beginthm|Exercise}} Show that a boundary of a well-connected $-dimensional symmetric/quadratic complex gives a boundary formation. {{endthm}} See section 2 of {{cite|Ranicki1980}} </wikitex> == References == {{#RefList:}} [[Category:Exercises]] [[Category:Exercises without solution]]\epsilon$ -symmetric/ $\epsilon$ -quadratic complex $(C, \phi)$ / $(C, \psi)$ is called well-connected if $H_0(C)= 0$ .

Show that a boundary of a well-connected $2$ -dimensional symmetric/quadratic complex gives a boundary formation.

See section 2 of [Ranicki1980]

[edit] References

[Ranicki1980] A. Ranicki, The algebraic theory of surgery. I. Foundations, Proc. London Math. Soc. (3) 40 (1980), no.1, 87–192. MR560997 (82f:57024a) Zbl 0471.57012

Formations and chain complexes II (Ex)

Latest revision as of 16:20, 31 May 2012

[edit] References

Personal tools

Namespaces

Variants

Views

Actions

Search

Navigation

Interaction

Toolbox

@@ Line 1: / Line 1: @@
 <wikitex>;
 {{beginthm|Definition|{{cite|Ranicki1980|Proposition 4.6}} }}
-An n-dimensional $\epsilon$-symmetric($\epsilon$-quadratic) complex $(C, \phi)$ ($(C, \psi)$) is called ''well-connected'' if $H_0(C)= 0$.
+An n-dimensional $\epsilon$-symmetric/$\epsilon$-quadratic complex $(C, \phi)$/$(C, \psi)$ is called ''well-connected'' if $H_0(C)= 0$.
 {{endthm}}