Mathematical Methods for Physics and Engineering : A Comprehensive Guide

8.7 THE COMPLEX AND HERMITIAN CONJUGATES OF A MATRIX

Find the complex conjugate of the matrix

A=

(

123 i

1+i 10

)

.

By taking the complex conjugate of each element we obtain immediately

A∗=

(

12 − 3 i

1 −i 10

)

.

The Hermitian conjugate, oradjoint,ofamatrixAis the transpose of its

complex conjugate, or equivalently, the complex conjugate of its transpose, i.e.

A†=(A∗)T=(AT)∗.

We note that ifAis real (and soA∗=A)thenA†=AT, and taking the Hermitian

conjugate is equivalent to taking the transpose. Following the previous line of

argument for the transpose of the product of several matrices, the Hermitian

conjugate of such a product can be shown to be given by

(AB···G)†=G†···B†A†. (8.40)

Find the Hermitian conjugate of the matrix

A=

(

123 i

1+i 10

)

.

Taking the complex conjugate ofAand then forming the transpose we find

A†=





11 −i

21

− 3 i 0



.

We obtain the same result, of course, if we first take the transpose ofAandthentakethe
complex conjugate.

An important use of the Hermitian conjugate (or transpose in the real case)

is in connection with the inner product of two vectors. Suppose that in a given

orthonormal basis the vectorsaandbmay be represented by the column matrices

a=











a 1

a 2

..

.

aN











and b=











b 1

b 2

..

.

bN











. (8.41)

Taking the Hermitian conjugate ofa, to give a row matrix, and multiplying (on