NORMAL MODES
P P P
llθ 1θ 1
θ 1θ 2 θ^2θ 2(a) (b) (c)Figure 9.1 A uniform rod of lengthlattached to the fixed pointPby a light
string of the same length: (a) the general coordinate system; (b) approximation
to the normal mode with lower frequency; (c) approximation to the mode with
higher frequency.With these expressions forTandVwe now apply the conservation of energy,d
dt(T+V)=0, (9.6)assuming that there are no external forces other than gravity. In matrix form
(9.6) becomes
d
dt(q ̇TAq ̇+qTBq)=q ̈TA ̇q+ ̇qTA ̈q+ ̇qTBq+qTB ̇q=0,which, usingA=ATandB=BT, gives
2 ̇qT(A ̈q+Bq)=0.We will assume, although it is not clear that this gives the only possible solution,
that the above equation implies that the coefficient of each ̇qiis separately zero.
Hence
A ̈q+Bq= 0. (9.7)For a rigorous derivation Lagrange’s equations should be used, as in chapter 22.
Nowwesearchforsetsofcoordinatesqthatalloscillate with the same period,i.e. the total motion repeats itselfexactlyafter afiniteinterval. Solutions of this
form will satisfy
q=xcosωt; (9.8)the relative values of the elements ofxin such a solution will indicate how each