Abstract
A wide range of vibrating structures are characterized by variable structural dynamics resulting from changes in environmental and operational conditions, posing challenges in their identification and associated condition assessment. To tackle this issue, the present contribution introduces a stochastic modeling methodology via Gaussian Process (GP) time-series models. In the presently introduced approach, the vibration response is represented by means of a random coefficient time-series model, whose coefficients comply with a GP regression on the environmental and operational parameters. The approach may be implemented in conjunction to any type of linear-in-the-parameters time-series model, ranging from simple AR models to more complex non-linear or non-stationary time-series models. The obtained GP time-series modeling approach provides an effective and compact global representation of the vibrational response of a structure under a wide span of environmental and operational conditions. The effectiveness of the postulated GP time-series models is demonstrated through two case studies: the first involves the identification of the vertical vibration response of the Humber bridge, evaluated over a period of three years; the second considers the long-term simulated vibration response of a wind turbine featuring non-stationary dynamics stemming from the rotor speed. In both cases, the variation of the average wind speed is the main driver of uncertainty, while, through application of the proposed GP time-series models, it is possible to track the resulting variation in modal quantities.
Highlights
Several types of vibrating structures by default operate in constantly varying environmental and operational conditions, which inevitably results in variability of the induced structural dynamics
This work provides a framework for the global identification of the dynamic response of a structure, of unknown properties or a given a priori numerical model, under variable operational and environmental conditions by representing the short-term dynamics via a linear-in-the parameters regressive time-series model, and a Gaussian Process (GP) regression to represent the stochastic dependence of the parameters of the basic time-series model on the Environmental and Operational Parameters (EOPs), which in turn, describes the long-term variability on the dynamics of the structural response
In the analysis presented here, the average wind speed on each analysis period is considered as the unique EOP for the construction of a GP-AR model of the vertical vibration of the bridge
Summary
Several types of vibrating structures by default operate in constantly varying environmental and operational conditions, which inevitably results in variability of the induced structural dynamics. In order to construct a robust model of the dynamic response of the structure, it is necessary to accurately model the short-term response of the structure, but it is further necessary to effectively capture the long-term trends underlying the induced dynamics This issue, in the particular case of data-based time-series models, has been extensively researched in recent years, resulting in the formulation of different strategies, including projection methods, and. Other sources of uncertainty may be misrepresented In this regard, this work provides a framework for the global (short and long term) identification of the dynamic response of a structure, of unknown properties or a given a priori numerical model, under variable operational and environmental conditions by representing the short-term dynamics via a linear-in-the parameters regressive time-series model (which may assume the form of an AutoRegressive, AutoRegressive with eXogenous input or similar model), and a Gaussian Process (GP) regression to represent the stochastic dependence of the parameters of the basic time-series model on the EOPs, which in turn, describes the long-term variability on the dynamics of the structural response.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
