Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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MATRICES AND VECTOR SPACES


Henceλ∗=−λand soλmust bepure imaginary(orzero). In a similar manner


to that used for Hermitian matrices, these properties may be proved directly.


8.13.3 Eigenvectors and eigenvalues of a unitary matrix

A unitary matrix satisfiesA†=A−^1 and is also a normal matrix, with mutually


orthogonal eigenvectors. To investigate the eigenvalues of a unitary matrix, we


note that ifAx=λxthen


x†x=x†A†Ax=λ∗λx†x,

and we deduce thatλλ∗=|λ|^2 = 1. Thus, the eigenvalues of a unitary matrix


have unit modulus.


8.13.4 Eigenvectors and eigenvalues of a general square matrix

When anN×Nmatrix is not normal there are no general properties of its


eigenvalues and eigenvectors; in general it is not possible to find any orthogonal


set ofNeigenvectors or even to findpairsof orthogonal eigenvectors (except


by chance in some cases). While theNnon-orthogonal eigenvectors are usually


linearly independent and hence form a basis for theN-dimensional vector space,


this is not necessarily so. It may be shown (although we will not prove it) that any


N×Nmatrix withdistincteigenvalues hasNlinearly independent eigenvectors,


which therefore form a basis for theN-dimensional vector space. If a general


square matrix has degenerate eigenvalues, however, then it may or may not have


Nlinearly independent eigenvectors. A matrix whose eigenvectors are not linearly


independent is said to bedefective.


8.13.5 Simultaneous eigenvectors

We may now ask under what conditions two different normal matrices can have


a common set of eigenvectors. The result – that they do so if, and only if, they


commute – has profound significance for the foundations of quantum mechanics.


To prove this important result letAandBbe twoN×Nnormal matrices and

xibe theith eigenvector ofAcorresponding to eigenvalueλi,i.e.


Axi=λixi for i=1, 2 ,... ,N.

For the present we assume that the eigenvalues are all different.


(i) First suppose thatAandBcommute. Now consider

ABxi=BAxi=Bλixi=λiBxi,

where we have used the commutativity for the first equality and the eigenvector


property for the second. It follows thatA(Bxi)=λi(Bxi) and thus thatBxiis an

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