9.3 RAYLEIGH–RITZ METHOD
and that this mode has the same frequency as three of the other modes. The
general topic of the degeneracy of normal modes is discussed in chapter 29. The
movements associated with the final two modes are shown in diagrams (g) and
(h) of figure 9.5; this figure summarises all eight normal modes and frequencies.
Although this example has been lengthy to write out, we have seen that theactual calculations are quite simple and provide the full solution to what is
formally a matrix eigenvalue equation involving 8×8 matrices. It should be
noted that our exploitation of the intrinsic symmetries of the system played a
crucial part in finding the correct eigenvectors for the various normal modes.
9.3 Rayleigh–Ritz methodWe conclude this chapter with a discussion of the Rayleigh–Ritz method for
estimating the eigenfrequencies of an oscillating system. We recall from the
introduction to the chapter that for a system undergoing small oscillations the
potential and kinetic energy are given by
V=qTBq and T= ̇qTA ̇q,where the components ofqare the coordinates chosen to represent the configura-
tion of the system andAandBare symmetric matrices (or may be chosen to be
such). We also recall from (9.9) that the normal modesxiand the eigenfrequencies
ωiare given by
(B−ω^2 iA)xi= 0. (9.14)It may be shown that the eigenvectorsxicorresponding to different normal modes
are linearly independent and so form a complete set. Thus, any coordinate vector
qcan be writtenq=
∑
jcjxj. We now consider the value of the generalisedquadratic form
λ(x)=xTBx
xTAx=∑
m(xm)Tc∗
mB∑
icixi
∑
j(xj)Tc∗
jA∑
kckxk,which, since both numerator and denominator are positive definite, is itself non-
negative. Equation (9.14) can be used to replaceBxi, with the result that
λ(x)=∑
m(xm)Tc∗
mA∑
iω2
icixi
∑
j(xj)Tc∗
jA∑
kckxk=∑
m(xm)Tc∗
m∑
iω2
iciAxi
∑
j(xj)Tc∗
jA∑
kckxk. (9.15)Now the eigenvectorsxiobtained by solving (B−ω^2 A)x= 0 are not mutually
orthogonal unless eitherAorBis a multiple of the unit matrix. However, it may