Affiliations: Applied Mechanics and Systems Research Laboratory,
Tunisia Polytechnic School, B.P. 743, La Marsa 2078, Tunisia | Department of Engineering Science and Mechanics, MC
0219, Virginia Polytechnic and State University, Blacksburg, VA 24061,
USA
Abstract: A design methodology for the vibration confinement of axial
vibrations in nonhomogenous rods is proposed. This is achieved by a proper
selection of a set of spatially dependent functions characterizing the rod
material and geometric properties. Conditions for selecting such properties are
established by constructing positive Lyapunov functions whose derivative with
respect to the space variable is negative. It is shown that varying the shape
of the rod alone is sufficient to confine the vibratory motion. In such a case,
the vibration confinement requires that the eigenfunctions be exponentially
decaying functions of space, where the notion of spatial domain stability is
introduced as a concept dual to that of the time domain stability. It is also
shown that vibration confinement can be produced if the rod density and/or
stiffness are varied with respect to the space variable while the cross-section
area is kept constant. Several case studies, supporting the developed
conditions imposed on the spatially dependent functions for vibration
confinement in vibrating rods, are discussed. Because variation in the
geometric and material properties might decrease the critical buckling loads,
we also discuss the buckling problem.
Keywords: axial vibration, vibration confinement, material and geometric properties, buckling
