Uncertainty reduction in residual stress measurements by an optimised inverse solution using nonconsecutive polynomials |
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Authors: | Diego L. Brítez Michael B. Prime Sana Werda Raynald Laheurte Philippe Darnis Olivier Cahuc |
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Affiliation: | 1. University of Bordeaux, CNRS, Bordeaux INP, I2M, UMR 5295, Talence, France;2. Los Alamos National Laboratory, New Mexico, USA |
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Abstract: | Many destructive methods for measuring residual stresses such as the slitting method require an inverse analysis to solve the problem. The accuracy of the result as well as an uncertainty component (the model uncertainty) depends on the basis functions used in the inverse solution. The use of a series expansion as the basis functions for the inverse solution was analysed in a previous work for the particular case where functions orders grew consecutively. The present work presents a new estimation of the model uncertainty and a new improved methodology to select the final basis functions for the case where the basis is composed of polynomials. Including nonconsecutive polynomial orders in the basis generates a larger space of possible solutions to be evaluated and allows the possibility to include higher-order polynomials. The paper includes a comparison with two other inverse analyses methodologies applied to synthetically generated data. With the new methodology, the final error is reduced and the uncertainty estimation improved. |
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Keywords: | inverse analysis residual stress measurement uncertainty estimation |
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