A Time-Domain DQ Approach for Vibration Analysis of Beams

A mixed method is presented to study the dynamic behavior of functionally graded (FG) beams subjected to moving loads. The theoretical formulations are based on Euler-Bernoulli beam theory, and the governing equations of motion of the system are derived using the Lagrange equations. The Rayleigh-Rit

A time-stepping model of a transversely vibrating, simply supported beam which allows the inclusion of non-linear damage such as a breathing crack is presented. It is based on the approximation that the mass and inertia of the beam may be lumped at points along the beam and the beam #exibility may b

The direct implementation of derivative boundary conditions at edge points was demonstrated to be simple, ¯exible and computationally ecient in the vibration analysis of beams and plates by using the dierential quadrature (DQ) method. In the approach, the discretized governing equations at certain i

A finite element time domain modal formulation is presented for the large amplitude free vibration of plates. The procedure of deriving the non-linear modal equations of motion is simple and general. Accurate frequency-maximum deflection relations can be obtained for the fundamental and higher non-l