Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

28.7 SUBDIVIDING A GROUP


this implies thatZbelongs toSY. These two results together mean that the two


subsetsSXandSYhave the same members and hence are equal.


Now suppose thatSXequalsSY.SinceYbelongs toSYit also belongs toSX

and henceX∼Y. This completes the proof of (i), once the distinct subsets of


typeSXare identified as the classesCi. Statement (ii) is an immediate corollary,


the class in question being identified asSW.


The most important property of an equivalence relation is as follows.

Two different subsetsSXandSYcan have no element in common, and the collection


of all the classesCiis a ‘partition’ ofS, i.e. every element inSbelongs to one, and


only one, of the classes.


To prove this, supposeSXandSYhave an elementZin common; thenX∼Z

andY∼Zand so by the symmetry and transitivity lawsX∼Y.Bytheabove


theorem this impliesSXequalsSY. But this contradicts the fact thatSXandSY


are different subsets. HenceSXandSYcan have no element in common.


Finally, if the elements ofSare used in turn to define subsets and hence classes

inS, every elementUis in the subsetSUthat is either a class already found or


constitutes a new one. It follows that the classes exhaustS,i.e.everyelementis


in some class.


Having established the general properties of equivalence relations, we now turn

to two specific examples of such relationships, in which the general setShas the


more specialised properties of a groupGand the equivalence relation∼is chosen


in such a way that the relatively transparent general results for equivalence


relations can be used to derive powerful, but less obvious, results about the


properties of groups.


28.7.2 Congruence and cosets

As the first application of equivalence relations we now prove Lagrange’s theorem


which is stated as follows.


Lagrange’s theorem.IfGis a finite group of ordergandHis a subgroup ofGof


orderhthengis a multiple ofh.


We take as the definition of∼that, givenXandYbelonging toG,X∼Yif

X−^1 Ybelongs toH. This is the same as saying thatY=XHifor some element


Hibelonging toH; technicallyXandYare said to be left-congruent with respect


toH.


This defines an equivalence relation, since it has the following properties.

(i) Reflexivity:X∼X,sinceX−^1 X=IandIbelongs to any subgroup.
(ii) Symmetry:X∼Yimplies thatX−^1 Ybelongs toHand so, therefore, does
its inverse, sinceHis a group. But (X−^1 Y)−^1 =Y−^1 Xand, as this belongs
toH, it follows thatY∼X.
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