Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

GROUP THEORY


(iii) Transitivity:X∼YandY∼Zimply thatX−^1 YandY−^1 Zbelong toH
and so, therefore, does their product (X−^1 Y)(Y−^1 Z)=X−^1 Z,fromwhich
it follows thatX∼Z.

With∼proved as an equivalence relation, we can immediately deduce that it

dividesGinto disjoint (non-overlapping) classes. For this particular equivalence


relation the classes are called theleft cosetsofH. Thus each element ofGis in


one and only one left coset ofH. The left coset containing any particularXis


usually writtenXH, and denotes the set of elements of the formXHi(one of


which isXitself sinceHcontains the identity element); it must containhdifferent


elements, since if it did not, and two elements were equal,


XHi=XHj,

we could deduce thatHi=Hjand thatHcontained fewer thanhelements.


From our general results about equivalence relations it now follows that the

left cosets ofHare a ‘partition’ ofGinto a number of sets each containingh


members. Since there aregmembers ofGand each must be in just one of the


sets, it follows thatgis a multiple ofh. This concludes the proof of Lagrange’s


theorem.


The number of left cosets ofHinGis known as theindexofHinGand is

written [G:H]; numerically the index =g/h. For the record we note that, for


the trivial subgroupI, which contains only the identity element, [G:I]=gand


that, for a subgroupJof subgroupH,[G:H][H:J]=[G:J].


The validity ofLagrange’s theoremwas established above using the far-reaching

properties of equivalence relations. However, for this specific purpose there is a


more direct and self-contained proof, which we now give.


LetXbe some particular element of a finite groupGof orderg,andHbe a

subgroup ofGof orderh, with typical elementYi. Consider the set of elements


XH≡{XY 1 ,XY 2 ,...,XYh}.

This set containshdistinct elements, since if any two were equal, i.e.XYi=XYj


withi=j, this would contradict the cancellation law. As we have already seen,


the set is called a left coset ofH.


We now prove three simple results.


  • Two cosets are either disjoint or identical.Suppose cosetsX 1 HandX 2 Hhave


an element in common, i.e.X 1 Y 1 =X 2 Y 2 for someY 1 ,Y 2 inH.ThenX 1 =
X 2 Y 2 Y 1 −^1 , and sinceY 1 andY 2 both belong toHso doesY 2 Y 1 −^1 ; thusX 1
belongs to the left cosetX 2 H. SimilarlyX 2 belongs to the left cosetX 1 H.
Consequently, either the two cosets are identical or it was wrong to assume
that they have an element in common.
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