Abstract
A mixture model approach is presented for combining the results of different models or analysis methods into a single probabilistic demand model for seismic assessment. In general, a structure can be represented using models of different type or different number of degrees of freedom, each offering a distinct compromise in computational load versus accuracy; it may also be analysed via methods of different complexity, most notably static versus dynamic nonlinear approaches. Employing the highest fidelity options is theoretically desirable but practically infeasible, at best limiting their use to calibrating or validating lower fidelity approaches. Instead, a large sample of low fidelity results can be selectively combined with sparse results from higher fidelity models or methods to simultaneously capitalize on the frugal nature of the former and the low bias of the latter to deliver fidelity at an acceptable cost. By employing a minimal 5 parameter power-law-based surrogate model we offer two options for forming mixed probabilistic seismic demand models that (i) can combine different models with varying degree of fidelity at different ranges of structural response, or (ii) nonlinear static and dynamic results into a single output suitable for fragility assessment.
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adopted from Aschheim et al. 2019)
source fragilities, the target, and the mixed fragility are presented
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Availability of data and material
The stripe analysis results of both Applications are available on GitHub: https://github.com/TheLambdaLab/MixedModels_paper.git, while the 2D models of the 4-story MRF are available at http://users.ntua.gr/divamva/RCbook.html
Code availability.
The code needed to replicate Applications 1 and 2 is available on GitHub: https://github.com/TheLambdaLab/MixedModels_paper.git.
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Acknowledgements
Financial support has been provided by the Eugenides Foundation in Greece (scholarship for doctoral studies in NTUA grant) and by the Innovation and Networks Executive Agency (INEA) under the powers delegated by the European Commission through the Horizon 2020 program “PANOPTIS-development of a decision support system for increasing the resilience of transportation infrastructure based on combined use of terrestrial and airborne sensors and advanced modelling tools”, Grant Agreement number 769129.
Funding
EU Horizon2020, Grant Agreement number 769129. Eugenides Foundation, Doctoral Grant Scholarship 2018.
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A. Chatzidaki: Formal analysis and investigation; Methodology; Writing—original draft preparation. D. Vamvatsikos: Conceptualization, Supervision, Writing—review and editing.
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Chatzidaki, A., Vamvatsikos, D. Mixed probabilistic seismic demand models for fragility assessment. Bull Earthquake Eng 19, 6397–6421 (2021). https://doi.org/10.1007/s10518-021-01163-4
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DOI: https://doi.org/10.1007/s10518-021-01163-4