CONCEPTS, DEFINITIONS AND METHODS                    21

        in  Figure 2.3(b), obtained with  N = 1. A  higher frequency component, at  01,  is  now
        superposed on the solution. Two observations should be made: (i) since, unrealistically,
        there is no damping in  the system, the effect of  initial conditions persists in perpetuity,
        whereas, with even a small amount of  damping, the steady-state response would be like
        that  in  Figure 2.3(a); (ii) since q/wf  is not  rational, the response is  not periodic but
        quasiperiodic, although  the  effect of  ‘unsteadiness’ in  the  response time-trace is just
        barely visible. This is more pronounced in Figure 2.3(c), plotted on an expanded time-
        scale, showing calculations with N = 2 and N = 4; in the latter case, the contribution of
        all four eigenmodes is visible. On the other hand, the period associated with the forcing
        frequency is hardly discernible in the time-scale used  in Figure 2.3(c).
          The fact that the response in  Figure 2.3(b,c) is quasiperiodic is most apparent in  the
        phase plane, as shown for example in Figure 2.4. It is seen that the response evolves by
        winding itself around a torus, the projection of  which is shown in the figure, instead of
        tracing a planar curve, as would be the case for periodic motion.

























        Figure 2.4  The response of Figure 2.3(b) plotted in the phase plane: the dimensionless tip velocity,
                               rj( 1, t), versus displacement, q( 1, t).

          There is another, more general method for obtaining the response of  such a system,
        specific to non-self-adjoint problems (Washizu 1966, 1968; Anderson 1972). This begins
        with the determination of the adjoint problem.+ If the eigenfunctions of the homogeneous
        form of equation (2.47), Le. of the compressively loaded beam, are xi(t) and those of the
        adjoint problem +;(e), the adjoint problem is defined through the new operators e* and
        Y*, such that

                                                                             (2.57)

        in which it is required that the so-called concomitant, C, vanish. A similar expression for
        M should be satisfied, but since for the problem at hand Y is a scalar, we immediately

          ‘Sometimes referred to as the adjugate problem (Collar & Simpson 1987).