Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

28.1 GROUPS


28.1.1 Definition of a group

AgroupGis a set of elements{X,Y,...}, together with a rule for combining


them that associates with each ordered pairX,Ya ‘product’ or combination law


X•Yfor which the following conditions must be satisfied.


(i) Foreverypair of elementsX, Ythat belongs toG, the productX•Yalso
belongs toG. (This is known as theclosure propertyof the group.)
(ii) For all triplesX, Y , Ztheassociative lawholds; in symbols,

X•(Y•Z)=(X•Y)•Z. (28.1)

(iii) There exists a unique elementI, belonging toG, with the property that

I•X=X=X•I (28.2)

forallXbelonging toG. This elementIis known as theidentity element
of the group.
(iv) For every elementXofG, there exists an elementX−^1 , also belonging to
G, such that

X−^1 • X=I=X•X−^1. (28.3)

X−^1 is called theinverseofX.

An alternative notation in common use is to write the elements of a groupG


as the set{G 1 ,G 2 ,...}or, more briefly, as{Gi}, a typical element being denoted


byGi.


It should be noticed that, as given, the nature of the operation•is not stated. It

should also be noticed that the more general termelement, rather thanoperation,


has been used in this definition. We will see that the general definition of a


group allows as elements not only sets of operations on an object but also sets of


numbers, of functions and of other objects, provided that the interpretation of•


is appropriately defined.


In one of the simplest examples of a group, namely the group of all integers

under addition, the operation•is taken to be ordinary addition. In this group the


role of the identityIis played by the integer 0, and the inverse of an integerXis


−X. That requirements (i) and (ii) are satisfied by the integers under addition is


trivially obvious. A second simple group, under ordinary multiplication, is formed


by the two numbers 1 and−1; in this group, closure is obvious, 1 is the identity


element, and each element is its own inverse.


It will be apparent from these two examples that the number of elements in a

group can be either finite or infinite. In the former case the group is called afinite


groupand the number of elements it contains is called theorderof the group,


which we will denote byg; an alternative notation is|G|but has obvious dangers

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