Shape Aware Quadratures

With Shape Aware Quadratures (SAQ), for a given set of quadrature nodes, order, and domain of integration, the quadrature weights are obtained by solving a system of suitable moment fitting equations in least square sense. The moments in the moment equations are approximated over a simplified domain...

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Bibliographic Details
Published in:Journal of computational physics 2018-12, Vol.374, p.1239-1260
Main Authors: Thiagarajan, Vaidyanathan, Shapiro, Vadim
Format: Article
Language:English
Subjects:
Approximation
Bivariate analysis
Computational physics
Divergence theorem
Domains
Integration
Mathematical analysis
Moment fitting equations
Numerical analysis
Numerical integration
Octree/quadtree
Polynomials
Quadratures
Sensitivity analysis
Shape sensitivity analysis
Theorems
Topological sensitivity analysis
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Summary:With Shape Aware Quadratures (SAQ), for a given set of quadrature nodes, order, and domain of integration, the quadrature weights are obtained by solving a system of suitable moment fitting equations in least square sense. The moments in the moment equations are approximated over a simplified domain (Ω0) that is a reasonable approximation of the original domain (Ω) that are then corrected for the deviation of the shape of Ω0 from Ω via shape correction factors. This idea was already successfully utilized in the Adaptively Weighted Numerical Integration (AW) method [1–3], where moments were computed over simplified but homeomorphic domain and then corrected using first-order shape sensitivity, allowing efficient and accurate integration of integrable functions over arbitrary domains. With SAQ, more general shape correction factors can be derived based on a variety of sensitivity analysis techniques such as shape sensitivity (SSA) and topological sensitivity (TSA). Using the right kind/order of shape correction factors for moment approximation enables the resulting quadrature (from the moment fitting equations) to efficiently adapt to the shape of the original domain even in the presence of thousands of small features. We derive shape correction factors based on SSA and TSA of moment integrals. We also demonstrate the efficacy of SAQ in integrating bivariate/trivariate polynomials over several 2D/3D domains in the presence of small features. •Non-trivial generalization of our earlier work (AW method) to efficiently account for topological features in addition to geometric features.•Generalization of the notion of moment approximations and correction factors using a variety of sensitivity analysis tools.•Detailed derivation of first/second-order shape and topological sensitivity of moment integrals.•Demonstration of polynomial integration over 2D/3D domains with several small features using non-conforming meshes.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2018.05.024