A DYNAMICAL BASIS FOR COMPUTING THE MODES OF EULER–BERNOULLI AND TIMOSHENKO BEAMS

In earlier papers [1,2], Naguleswaran studied the vibrations of beams with non-uniform thickness by solving the differential equation with the Frobenius method, which gives the solutions in infinite power series. The author observed the fact that, for some cases, even the quadruple precision could n

This paper presents a new Dynamic Finite Element (DFE) formulation for the vibrational analysis of spinning beams. A non-dimensional formulation is adopted, and the frequency dependent trigonometric shape functions are used to find a simple frequency dependent element stiffness matrix which has both

The quasi-static and dynamic responses of a linear viscoelastic Timoshenko beam on Winkler foundation are studied numerically by using the hybrid Laplace-Carson and finite element method. In this analysis the field equation for viscoelastic material is used. In the transformed Laplace-Carson space t

## Abstract The stabilization of a symmetric tree‐shaped network of Euler–Bernoulli beams described by a system of partial differential equations is considered. The boundary controllers are designed based on passivity principle. The eigenfrequencies are analysed in detail and the asymptotic expansi