Mathematical Methods for Physics and Engineering : A Comprehensive Guide

MATRICES AND VECTOR SPACES

may be shown that the rank of a generalM×Nmatrix is equal to the size of

the largest square submatrix ofAwhose determinant is non-zero. Therefore, if a

matrixAhas anr×rsubmatrixSwith|S|= 0, but no (r+1)×(r+ 1) submatrix

with non-zero determinant then the rank of the matrix isr. From either definition

it is clear that the rank ofAis less than or equal to the smaller ofMandN.

Determine the rank of the matrix

A=





110 − 2

202 2

413 1



.

The largest possible square submatrices ofAmust be of dimension 3×3. Clearly,A
possesses four such submatrices, the determinants of which are given by
∣∣
∣
∣∣
∣

110

202

413

∣∣

∣

∣∣

∣

=0,

∣∣

∣

∣∣

∣

11 − 2

20 2

41 1

∣∣

∣

∣∣

∣

=0,

∣

∣∣

∣

∣∣

10 − 2

22 2

43 1

∣

∣∣

∣

∣∣=0,

∣

∣∣

∣

∣∣

10 − 2

02 2

13 1

∣

∣∣

∣

∣∣=0.

(In each case the determinant may be evaluated as described in subsection 8.9.1.)
The next largest square submatrices ofAare of dimension 2×2. Consider, for example,
the 2×2 submatrix formed by ignoring the third row and the third and fourth columns
ofA; this has determinant
∣
∣∣
∣

11

20

∣

∣∣

∣=1×^0 −^2 ×1=−^2.

Since its determinant is non-zero,Ais of rank 2 and we need not consider any other 2× 2
submatrix.

In the special case in which the matrixAis asquareN×Nmatrix, by comparing

either of the above definitions of rank with our discussion of determinants in

section 8.9, we see that|A|= 0 unless the rank ofAisN.Inotherwords,Ais

singularunlessR(A)=N.

8.12 Special types of square matrix

Matrices that are square, i.e.N×N, are very common in physical applications.

We now consider some special forms of square matrix that are of particular

importance.

8.12.1 Diagonal matrices

The unit matrix, which we have already encountered, is an example of adiagonal

matrix. Such matrices are characterised by having non-zero elements only on the