Method of manufactured solutions code verification of elastostatic solid mechanics problems in a commercial finite element solver

Aycock, Kenneth I.; Rebelo, Nuno; Craven, Brent A.

doi:10.1016/j.compstruc.2019.106175

Cited by 8 publications

(2 citation statements)

References 31 publications

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“…Code verification Software quality assurance (SQA) (a) Very little or no SQA procedures were specified or followed (b) SQA procedures were specified and documented (c) In addition to the previously specified SQA procedures, the software anomaly list and the software development environment are fully understood and the impact on the COU is analyzed and documented; quality metrics are tracked Numerical code verification (NCV) (a) NCV was not performed (b) The numerical solution was compared to an accurate benchmark solution from another verified code (c) The numerical solution was compared to an accurate benchmark solution, either an analytical solution or using the method of manufactured solutions (MMS) [36] Calculation The calculation verification was also performed through a mesh convergence analysis of the FE model and the results are presented in Table 5. In this work, we used the fully automatic adaptive meshing convergence tool provided by ANSYS Workbench; this process provides the desired accuracy in the smallest number of runs possible.…”

Section: Factor Goalsmentioning

confidence: 99%

“…In this paper, rigorous code verification was not performed since it out of the scope. For future studies, a rigorous verification is recommended, using, for example, the method of manufactured solutions (MMSs) that has successfully been applied to commercial finite element code for elastostatic solid mechanics analyses [36]. Although numerical error estimation was out of the scope of this paper, it is recommended the future studies involving rigorous mesh refinement using Richardson extrapolation and calculations of a grid convergence index should be performed [47].…”

Section: Contribution and Future Studiesmentioning

confidence: 99%

See 1 more Smart Citation

Uncertainty Quantification With Sparsely Characterized Parameters: An Example Applied to Femoral Stem Mechanics

Wanki

Ekwaro-Osire

Dias

et al. 2020

Journal of Verification, Validation and Uncertainty Quantification

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The advent of state-of-the-art additive manufacturing (AM) processes has facilitated the manufacturing of complex orthopedic metallic implants such as femoral stems with porous portions based on lattice structures. These struts often have rough and not smooth textured surfaces, for which the irregularities may influence mechanical properties. To make robust predictions about the behavior of this kind of system, the variability of the mechanical properties and its impact on the stem stiffness must be considered in the processes of modeling and design of porous femoral stems. Also, to improve the credibility of computational models used for hip implant analysis, which involves numerous uncertainties, there is a need for rigorous uncertainty quantification (UQ) framework for proper model assessment following a credible-modeling standard. In this sense, this work proposes a UQ framework for analyzing a femoral stem implant model, to clarify how uncertainties impact the key properties of a porous femoral stem. In this study, uncertainties in the strut thickness, pore size, Young modulus, and external forcing are considered. A robust UQ framework is proposed and validated using experimental results available from literature, following the guidelines set in an AMSE standard. This study has a contribution in assessing the effect of input parameter uncertainties on femoral stem stiffness and the surface-to-volume ratio of porous stems.

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Section: Factor Goalsmentioning

confidence: 99%

Section: Contribution and Future Studiesmentioning

confidence: 99%