Probabilistic Validation of the Housner Rocking Model

Bachmann, Jonas A.; Strand, Mathias; Vassiliou, Michalis F.; Broccardo, Marco; Stojadinović, Božidar

doi:10.7712/120117.5623.18485

Cited by 2 publications

(2 citation statements)

References 35 publications

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“…On the other hand, rocking structures are capable of uplifting and sustaining a strong nonlinear motion, while limiting the development of base moments since they are not fixed to the foundation or the ground (Thiers-Moggia and Málaga-Chuquitaype, 2021). It has been proposed that this uplift can act as a sort of rocking isolation for both bridges and buildings (Bachmann et al, 2019; Thiers-Moggia and Málaga-Chuquitaype, 2020; Vassiliou et al, 2021). However, until recently it was been believed that analytical or numerical models can not accurately predict the rocking motion, as many efforts faced frequent failure in the recreation of experimental data (ElGawady et al, 2011; Kalliontzis and Sritharan, 2018).…”

Section: Introductionmentioning

confidence: 99%

Physics-informed artificial intelligence models for the seismic response prediction of rocking structures

Shen,

Málaga-Chuquitaype

2024

DCE

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The seismic response of a wide variety of structures, from small but irreplaceable museum exhibits to large bridge systems, is characterized by rocking. In addition, rocking motion is increasingly being used as a seismic protective strategy to limit the amount of seismic actions (moments) developed at the base of structures. However, rocking is a highly nonlinear phenomenon governed by non-smooth dynamic phases that make its prediction difficult. This study presents an alternative approach to rocking estimation based on a physics-informed convolutional neural network (PICNN). By training a group of PICNNs using limited datasets obtained from numerical simulations and encoding the known physics into the PICNNs, important predictive benefits are obtained relieving difficulties associated with over-fitting and minimizing the requirement for a large training database. Two models are created depending on the validation of the deep PICNN: the first model assumes that state variables including rotations and angular velocities are available, while the second model is useful when only acceleration measurements are known. The analysis is initiated by implementing K-means clustering. This is followed by a detailed statistical assessment and a comparative analysis of the response-histories of a rocking block. It is observed that the deep PICNN is capable of effectively estimating the seismic rocking response history when the rigid block does not overturn.

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Section: Introductionmentioning

confidence: 99%

Physics-informed artificial intelligence models for the seismic response prediction of rocking structures

Shen,

Málaga-Chuquitaype

2024

DCE

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“…In parallel, conventional validation test of numerically reproducing the experimentally obtained response to a particular ground motion with acceptable accuracy is too strict of a validation test for structural models [13,14]. The Earthquake Engineering design problem involves predicting the statistics of the response to an ensemble of ground motions characterizing a given seismic hazard; not to a single ground motion.…”

Section: Introduction: the Need For Small Scale Testingmentioning

confidence: 99%

Material Testing of Micro-Concrete and 3d-Printed Reinforcement for Use in Small-Scale Seismic Testing of Rc Structures

Elmorsy,

Wrobel,

Leinenbach

et al. 2023

Proceedings of the 8th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COM

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A framework for small scale modeling of RC structures that helps understanding their seismic behavior is discussed in this paper. The framework includes testing of small scale RC buildings manufactured using micro concrete and additively manufactured (3D printed) reinforcement cages on a shake table mounted on a geotechnical centrifuge. This paper presents material level testing of micro-concrete and 3D printed reinforcement that are to be used in the proposed framework. Mechanical properties of the 3D printed rebars are first discussed and compared to full scale rebar mechanical properties. A Concept Laser M2 Laser Powder Bed Fusion (LPBF) printer is used for printing the rebars. In addition, the compressive and tensile behavior of micro-concrete are studied using small scale cylinders and beams (for four-point bending tests), respectively. The results of this paper reveal that the mechanical properties of 3D printed submillimeter rebars can be adjusted by modulating the printing parameters. Moreover, concrete mechanical properties that are suitable for the discussed framework can be achieved.

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Probabilistic Validation of the Housner Rocking Model

Cited by 2 publications

References 35 publications

Physics-informed artificial intelligence models for the seismic response prediction of rocking structures

Physics-informed artificial intelligence models for the seismic response prediction of rocking structures

Material Testing of Micro-Concrete and 3d-Printed Reinforcement for Use in Small-Scale Seismic Testing of Rc Structures

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