On the use of elliptic PDEs for the parameterisation of planar multipatch domains Part 1: Numerical algorithms and foundations of parametric control

• Published in: Engineering with computers Vol. 40; no. 6; pp. 3735 - 3764
• Main Authors: Hinz, Jochen, Buffa, Annalisa
• Format: Journal Article
• Language: English
• Published: London Springer London 01.01.2024
• Subjects: CAE) and Design; Calculus of Variations and Optimal Control; Optimization; Classical Mechanics; Computer Science; Computer-Aided Engineering (CAD; Control; Math. Applications in Chemistry; Mathematical and Computational Engineering; Original; Original Article; Systems Theory; Isogeometric analysis; Harmonic maps; Parameterisation techniques
• ISSN: 0177-0667; 1435-5663
• DOI: 10.1007/s00366-024-01997-x

This paper presents a parameterisation framework based on (inverted) elliptic PDEs for addressing the planar parameterisation problem of finding a valid description of the domain’s interior given no more than a spline-based description of its boundary contours. The framework is geared towards isogeometric analysis (IGA) applications wherein the physical domain is comprised of more than four sides, hence requiring more than one patch. We adopt the concept of harmonic maps and propose several PDE-based problem formulations capable of finding a valid map between a convex parametric multipatch domain and the piecewise-smooth physical domain with an equal number of sides. In line with the isoparametric paradigm of IGA, we treat the parameterisation problem using techniques that are characteristic for the analysis step. As such, this study proposes several IGA-based numerical algorithms for the problem’s governing equations that can be effortlessly integrated into a well-developed IGA software suite. We augment the framework with mechanisms that enable controlling the parametric properties of the outcome. Parametric control is accomplished by, among other techniques, the introduction of a curvilinear coordinate system in the convex parametric domain, for which more general elliptic PDEs are adopted. Depending on the application, parametric control allows for building desired features into the computed map, such as homogeneous cell sizes or boundary layers.