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arxiv: 1902.01814 · v2 · pith:OCR5UWT7new · submitted 2019-02-05 · 🧮 math.NA · cs.CG· cs.NA· math.AG

A non-iterative method for robustly computing the intersections between a line and a curve or surface

classification 🧮 math.NA cs.CGcs.NAmath.AG
keywords methodintersectionsalgebraalgebraicavailablecomputingcurvefinite
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The need to compute the intersections between a line and a high-order curve or surface arises in a large number of finite element applications. Such intersection problems are easy to formulate but hard to solve robustly. We introduce a non-iterative method for computing intersections by solving a matrix singular value decomposition (SVD) and an eigenvalue problem. That is, all intersection points and their parametric coordinates are determined in one-shot using only standard linear algebra techniques available in most software libraries. As a result, the introduced technique is far more robust than the widely used Newton-Raphson iteration or its variants. The maximum size of the considered matrices depends on the polynomial degree $q$ of the shape functions and is $2q \times 3q$ for curves and $6 q^2 \times 8 q^2$ for surfaces. The method has its origin in algebraic geometry and has here been considerably simplified with a view to widely used high-order finite elements. In addition, the method is derived from a purely linear algebra perspective without resorting to algebraic geometry terminology. A complete implementation is available from http://bitbucket.org/nitro-project/.

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