The (small) vibrations of thin plates
This work provides a novel numerical approach for vibration analysis of thin plates, but the results are incremental as they only validate against known patterns without demonstrating improved accuracy or efficiency.
The authors developed a numerical scheme for solving linearized elastodynamic equations for thin plates, discretizing solutions using PL vector fields on barycentric subdivisions. Their method produced resonance mode approximations consistent with experimental results.
We describe the equations of motion of elastodynamic bounded bodies in 3-space, and their linearizations at a stationary point. Using the latter as an approximation to model small motions, we develop a scheme to find numerical solutions of these equations. We discretize the solution in the space of PL vector fields associated to the oriented faces of the first barycentric subdivision of a given smooth initial triangulation of the body, in order to exploit the algebraic topology properties of the body that these vector fields encode into the sought after solution, and solve a weak version of the linearized equations in that context. We apply our scheme to a couple of relevant examples of thin bodies, bodies where one of the dimensions is at least one order of magnitude in size less than the other two, and determine numerical approximations to some of their resonance modes of vibration. The results obtained are consistent with known vibration patterns for these bodies derived experimentally.