This thesis performs a dynamic finite element analysis of a planar fully parallel robot with flexible links. The governing equations of motion are based on the linear theory of kineto-elastodynamics.

Results show that:​

• Convergence of the responses is achieved when each link is modeled with only one axially extendible high-order beam element, resulting in twelve flexible degrees-of-freedom;​
• The first mode's natural frequency (ω₁) varies significantly with the configuration, from zero Hertz to more than 500 Hertz. A large ω₁ is associated with stiff configurations and warrants small amplitude dynamic vibrations. In contrast, a low ω1 can lead to relatively large amplitude vibrations, provided that this mode is excited by the input motion;​
• The additional terms included in the governing equations of motion, namely Coriolis damping, and centrifugal and geometric stiffnesses, have a negligible contribution to the vibratory response in the present analysis.