The maximization of radiated sound power from baffled vibrating structures
is studied as a means of examining the structural-acoustic control authorit
y of point force and distributed moment actuators. The relationship between
the structural vibration and radiated sound power is expressed as a quadra
tic function of the modal velocities and the structural mode shapes. The so
und power model is nondimensionalized through geometric transformations. Th
e problem of computing the maximum radiated acoustic power using an array o
f actuators is shown to reduce to a generalized eigenvalue analysis. A term
denoting the power efficiency, which is defined as the ratio of maximum ra
diated power normalized with respect to the maximum achievable radiated pow
er, is stated and a series of numerical simulations are performed. The nume
rical simulations examine the physical mechanisms of maximizing the sound p
ower output of structures. The expressions for the modal coefficients of po
int force and distributed moment actuators are used to determine actuator l
ocations that influence only the efficient radiator modes. Power efficiency
studies illustrate the relationship between the modal velocities and the d
irection of the maximizing force input. The numerical studies indicate that
a group of properly placed point force actuators can achieve broadband pow
er efficiency over the frequency range studied, whereas distributed moment
actuation exhibits lower power efficiency at high frequencies. This differe
nce is attributed to the magnitude and phasing of the array modal velocitie
s. The simulations also demonstrate the utility of the eigenvalue technique
for determining optimal placement and sizing of a multiple transducer air-
acoustic actuator array.