Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

MATRICES AND VECTOR SPACES


This set of equations is also triangular, and we easily find the solution


x 1 =2,x 2 =− 3 ,x 3 =4,

which agrees with the result found above by direct inversion.


We note, in passing, that one can calculate both the inverse and the determinant

ofAfrom itsLUdecomposition. To find the inverseA−^1 , one solves the system


of equationsAx=brepeatedly for theNdifferent RHS column matricesb=ei,


i=1, 2 ,...,N,whereeiis the column matrix with itsith element equal to unity


and the others equal to zero. The solutionxin each case gives the corresponding


column ofA−^1. Evaluation of the determinant|A|is much simpler. From (8.125),


we have


|A|=|LU|=|L||U|. (8.127)

SinceLandUare triangular, however, we see from (8.64) that their determinants


are equal to the products of their diagonal elements. SinceLii= 1 for alli,we


thus find


|A|=U 11 U 22 ···UNN=

∏N

i=1

Uii.

As an illustration, in the above example we find|A|= (2)(−4)(− 11 /8) = 11,


which, as it must, agrees with our earlier calculation (8.58).


Finally, we note that if the matrixAis symmetric and positive semi-definite

then we can decompose it as


A=LL†, (8.128)

whereLis a lower triangular matrix whose diagonal elements arenot, in general,


equal to unity. This is known as aCholesky decomposition(in the special case


whereAis real, the decomposition becomesA=LLT). The reason that we cannot


set the diagonal elements ofLequal to unity in this case is that we require the


same number of independent elements inLas inA. The requirement that the


matrix be positive semi-definite is easily derived by considering the Hermitian


form (or quadratic form in the real case)


x†Ax=x†LL†x=(L†x)†(L†x).

Denoting the column matrixL†xbyy, we see that the last term on the RHS


isy†y, which must be greater than or equal to zero. Thus, we requirex†Ax≥ 0


for any arbitrary column matrixx,andsoAmust be positive semi-definite (see


section 8.17).


We recall that the requirement that a matrix be positive semi-definite is equiv-

alent to demanding that all the eigenvalues ofAare positive or zero. If one of


the eigenvalues ofAis zero, however, then from (8.103) we have|A|= 0 and soA


issingular. Thus, ifAis a non-singular matrix, it must bepositive definite(rather

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