Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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8.12 SPECIAL TYPES OF SQUARE MATRIX


leading diagonal, i.e. only elementsAijwithi=jmay be non-zero. For example,


A=



10 0
02 0
00 − 3


,

is a 3×3 diagonal matrix. Such a matrix is often denoted byA= diag (1, 2 ,−3).


By performing a Laplace expansion, it is easily shown that the determinant of an


N×Ndiagonal matrix is equal to the product of the diagonal elements. Thus, if


the matrix has the formA= diag(A 11 ,A 22 ,...,ANN)then


|A|=A 11 A 22 ···ANN. (8.63)

Moreover, it is also straightforward to show that the inverse ofAis also a


diagonal matrix given by


A−^1 = diag

(
1
A 11

,

1
A 22

,...,

1
ANN

)
.

Finally, we note that, if two matricesAandBarebothdiagonal then they have


the useful property that their product is commutative:


AB=BA.

This isnottrue for matrices in general.


8.12.2 Lower and upper triangular matrices

A square matrixAis calledlower triangularif all the elementsabovethe principal


diagonal are zero. For example, the general form for a 3×3 lower triangular


matrix is


A=



A 11 00
A 21 A 22 0
A 31 A 32 A 33


,

where the elementsAijmay be zero or non-zero. Similarly anupper triangular


square matrix is one for which all the elementsbelowthe principal diagonal are


zero. The general 3×3 form is thus


A=



A 11 A 12 A 13
0 A 22 A 23
00 A 33


.

By performing a Laplace expansion, it is straightforward to show that, in the


generalN×Ncase, the determinant of an upper or lower triangular matrix is


equal to the product of its diagonal elements,


|A|=A 11 A 22 ···ANN. (8.64)
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