A procedure for the identification of linear and non-linear multi-degree-of-freedom systems

System identification for non-linear dynamical systems could find use in many applications such as condition monitoring, finite element model validation and determination of stability. The effectiveness of existing non-linear system identification techniques is limited by various factors such as the

Classical force appropriation methods are used in the identi"cation of linear systems to determine the multi-point force vector that will induce single-mode behaviour, thus allowing each normal mode to be identi"ed in isolation. This paper presents an extension to this linear approach that will enab

This paper presents a new frequency-domain method to analyze physically non-linear structural systems having non-proportional damping. Single-and multi-degree-of-freedom (d.o.f.) systems subjected to time-dependent excitations are considered. A procedure to consider initial conditions, required by t

Conventional frequency response estimation methods such as the ''H1'' and ''H2'' methods often yield measured frequency response functions which are contaminated by the presence of non-linearities and hence make it difficult to extract underlying linear system properties. To overcome this deficiency