The linear dynamics of nearly periodic disordered multi-span beams resting
on flexible supports are investigated. A wave transfer matrix methodology i
s chosen to examine the propagation of waves and the transmission of vibrat
ion along the structure. The spans are bi-coupled through the rotation and
the transverse displacement at the supports and thus the beam motion is mad
e up of two independent wave types. While for the ordered infinite beam the
re exists frequency passbands for which the free harmonic waves propagate w
ithout attenuation, the introduction of a slight disorder among the span le
ngths results in the localization of the vibration energy to few spans and
in the conversion of the energy from one type of wave to the other. The ene
rgy conversion phenomenon renders the mechanism of localization much more c
omplex than in mono-coupled periodic systems. The contribution of each type
of wave to the global beam motion is analyzed in terms of frequency. It is
observed that the spatial decay of each wave type is mainly governed by an
exponential envelope. The corresponding exponential decay constants define
a measure of localization for each wave and are found to be equal to the L
yapunov exponents of the product of random wave transfer matrices. It is al
so found that at frequencies which belong to a passband for both wave types
, the decay rate of an incident wave vector is bounded by the two Lyapunov
exponents, while at frequencies which belong to a passband for one wave typ
e and a stopband for the other, localization effects are best predicted by
the smallest of the two Lyapunov exponents. (C) 2000 Published by Elsevier
Science Ltd. All rights reserved.