Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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8.9 THE DETERMINANT OF A MATRIX


which shows that the trace of a multiple product is invariant under cyclic


permutations of the matrices in the product. Other easily derived properties of


the trace are, for example, TrAT=TrAand TrA†=(TrA)∗.


8.9 The determinant of a matrix

For a given matrixA, the determinant detA(like the trace) is a single number (or


algebraic expression) that depends upon the elements ofA. Also like the trace,


the determinant is defined only forsquarematrices. If, for example,Ais a 3× 3


matrix then its determinant, oforder3, is denoted by


detA=|A|=







A 11 A 12 A 13
A 21 A 22 A 23
A 31 A 32 A 33







. (8.45)


In order to calculate the value of a determinant, we first need to introduce

the notions of theminorand thecofactorof an element of a matrix. (We


shall see that we can use the cofactors to write an order-3 determinant as the


weighted sum of three order-2 determinants, thereby simplifying its evaluation.)


The minorMijof the elementAijof anN×NmatrixAis the determinant of


the (N−1)×(N−1) matrix obtained by removing all the elements of theith


row andjth column ofA; the associated cofactor,Cij, is found by multiplying


the minor by (−1)i+j.


Find the cofactor of the elementA 23 of the matrix

A=




A 11 A 12 A 13


A 21 A 22 A 23


A 31 A 32 A 33



.


Removing all the elements of the second row and third column ofAand forming the
determinant of the remaining terms gives the minor


M 23 =






A 11 A 12


A 31 A 32





∣.


Multiplying the minor by (−1)2+3=(−1)^5 =−1gives


C 23 =−




∣∣A^11 A^12


A 31 A 32




∣∣.


We now define a determinant asthe sum of the products of the elements of any

row or column and their corresponding cofactors,e.g.A 21 C 21 +A 22 C 22 +A 23 C 23 or


A 13 C 13 +A 23 C 23 +A 33 C 33. Such a sum is called aLaplace expansion. For example,


in the first of these expansions, using the elements of the second row of the

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