UV mapping is a classical problem in computer graphics aiming at computing a planar parameterization of the input mesh with the lowest possible distortion while minimizing the seams length. Recent works propose optimization methods for solving these two joint problems at the same time with variational models, but they tend to be slower than other cutting methods. We present a new variational approach for this problem inspired by the Ambrosio-Tortorelli functional, which is easier to optimize than already existing methods. This functional has widely been used in image and geometry processing for anisotropic denoising and segmentation applications. The key feature of this functional is to model both regions where smoothing is applied, and the loci of discontinuities corresponding to the cuts. Our approach relies on this principle to model both the low distortion objective of the UV map, and the minimization of the seams length (sequences of mesh edges). Our method significantly reduces the distortion in a faster way than state-of-the art methods, with comparable seam quality. We also demonstrate the versatility of the approach when external constraints on the parameterization is provided (packing constraints, seam visibility).
@article{uv-at,
author = {Colin Weill–Duflos and David Coeurjolly and Fernando de Goes and Jacques-Olivier Lachaud},
journal = {Computer Aided Geometric Design (Proc. of GMP 2023)},
month = {July},
note = {(to appear)},
title = {Joint optimization of distortion and cut location for mesh parameterization using an Ambrosio-Tortorelli functional},
year = {2023}
}