Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

MATRICES AND VECTOR SPACES


may be thought of as ‘transforming’ one geometrical entity (i.e. a vector) into


another.


If we now introduce a basisei,i=1, 2 ,...,N, into our vector space then the

action ofAon each of the basis vectors is to produce a linear combination of


the latter; this may be written as


Aej=

∑N

i=1

Aijei, (8.23)

whereAijis theith component of the vectorAejin this basis; collectively the


numbersAijare called the components of the linear operator in theei-basis.In


this basiswe can express the relationy=Axin component form as


y=

∑N

i=1

yiei=A



∑N

j=1

xjej


=

∑N

j=1

xj

∑N

i=1

Aijei,

and hence, in purely component form, in this basis we have


yi=

∑N

j=1

Aijxj. (8.24)

If we had chosen a different basise′i, in which the components ofx,yandA


arex′i,y′iandA′ijrespectively then the geometrical relationshipy=Axwould be


represented in this new basis by


y′i=

∑N

j=1

A′ijx′j.

We have so far assumed that the vectoryis in the same vector space as

x.If,however,ybelongs to a different vector space, which may in general be


M-dimensional (M=N) then the above analysis needs a slight modification. By


introducing a basis setfi,i=1, 2 ,...,M, into the vector space to whichybelongs


we may generalise (8.23) as


Aej=

∑M

i=1

Aijfi,

where the componentsAijof the linear operatorArelate to both of the basesej


andfi.

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