TY - JOUR AB - Purpose This paper aims to present the development of a numerical continuum-discrete approach for computing the sensitivity of the waves propagating in periodic composite structures. The work can be directly used for evaluating the sensitivity of the structural dynamic performance with respect to geometric and layering structural modifications.Design/methodology/approach A structure of arbitrary layering and geometric complexity is modelled using solid finite element (FE). A generic expression for computing the variation of the mass and the stiffness matrices of the structure with respect to the material and geometric characteristics is hereby given. The sensitivity of the structural wave properties can thus be numerically determined by computing the variability of the corresponding eigenvalues for the resulting eigenproblem. The exhibited approach is validated against the finite difference method as well as analytical results.Findings An intense wavenumber dependence is observed for the sensitivity results of a sandwich structure. This exhibits the importance and potential of the presented tool with regard to the optimization of layered structures for specific applications. The model can also be used for computing the effect of the inclusion of smart layers such as auxetics and piezoelectrics.Originality/value The paper presents the first continuum-discrete approach specifically developed for accurately and efficiently computing the sensitivity of the wave propagation data for periodic composite structures irrespective of their size. The considered structure can be of arbitrary layering and material characteristics as FE modelling is used. VL - 34 IS - 5 SN - 0264-4401 DO - 10.1108/EC-06-2016-0200 UR - https://doi.org/10.1108/EC-06-2016-0200 AU - Chronopoulos Dimitrios AU - Collet Manuel AU - Ichchou Mohamed PY - 2017 Y1 - 2017/01/01 TI - Wave sensitivity analysis for periodic and arbitrarily complex composite structures T2 - Engineering Computations PB - Emerald Publishing Limited SP - 1572 EP - 1597 Y2 - 2024/09/23 ER -