1000 Solved Problems in Modern Physics

1.3 Solutions 47

1.31 A=

⎛

⎝

6 − 22

− 23 − 1

2 − 13

⎞

⎠

In Problem 1.30, the characteristic roots are found to beλ= 2 , 2 ,8. With

λ=2, we find the invariant vectors.

⎛

⎝

6 − 2 − 22

− 23 − 2 − 1

2 − 13 − 2

⎞

⎠

⎛

⎝

x 1

x 2

x 3

⎞

⎠= 0

The two vectors areX 1 =(1, 1 ,−1)′andX 2 =(0, 1 ,1)′. The third vector

can be obtained in a similar fashion. It can be chosen asX 3 =(2,− 1 ,1)′.The

three column vectors can be normalized and arranged in the form of a matrix.

The matrixAis diagnalized by the similarity transformation.

S−^1 AS=diagA

S=

⎛

⎜

⎝

√^1

3 0

√^2

6

√^1

3

√^1

2 −

√^1

6

−√^13 √^12 √^16

⎞

⎟

⎠

As the matrixSis orthogonal,S−^1 =S′. Thus

⎛

⎜

⎝

√^1

3

√^1

3 −

√^1

3

0 √^12 √^12

√^2

6 −

√^1

6

√^1

6

⎞

⎟

⎠

⎛

⎝

6 − 22

− 23 − 1

2 − 13

⎞

⎠

⎛

⎜

⎝

√^1

3 0

√^2

6

√^1

3

√^1

2 −

√^1

6

−√^13 √^12 √^16

⎞

⎟

⎠=

⎛

⎝

200

020

008

⎞

⎠

1.32 H=

(

a 11 a 12

a 21 a 22

)

A=

[

32

41

]

(a)

∣

∣

∣

∣

3 −λ 2

41 −λ

∣

∣

∣

∣=0, characteristic equation is

(3−λ)(1−λ)− 8 = 0

λ^2 − 4 λ− 5 = 0 ,(λ−5)(λ+1)= 0

The eigen values areλ 1 =5 andλ 2 =− 1

(b) and (c) The desired matrix has the form

C=

(

C 11 C 12

C 21 C 22

)

The columns which satisfy the system of equations

(aij−δijλk)Cjk= 0 ,no sum onk (1)

yielding

(a 11 −λk)C 1 k+a 12 C 2 k= 0 ,no sum onk

a 21 C 1 k+(a 22 −λk)C2k= 0 ,k= 1 , 2

Sincea 11 =3,a 21 =4,a 12 =2,a 22 =1, we get