TL;DR
This paper presents a new geometric multigrid solver for unstructured curved surfaces that uses intrinsic geometry for prolongation, significantly improving convergence and speed over existing methods in geometry processing tasks.
Contribution
A novel intrinsic geometry-based prolongation operator for multigrid methods on curved surfaces, enabling efficient and faster solvers for complex geometry processing applications.
Findings
Achieves better convergence than existing multigrid methods.
Orders of magnitude faster than direct solvers.
Enables interactive performance in geometry processing tasks.
Abstract
This paper introduces a novel geometric multigrid solver for unstructured curved surfaces. Multigrid methods are highly efficient iterative methods for solving systems of linear equations. Despite the success in solving problems defined on structured domains, generalizing multigrid to unstructured curved domains remains a challenging problem. The critical missing ingredient is a prolongation operator to transfer functions across different multigrid levels. We propose a novel method for computing the prolongation for triangulated surfaces based on intrinsic geometry, enabling an efficient geometric multigrid solver for curved surfaces. Our surface multigrid solver achieves better convergence than existing multigrid methods. Compared to direct solvers, our solver is orders of magnitude faster. We evaluate our method on many geometry processing applications and a wide variety of complex…
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