Parallel and Scalable Heat Methods for Geodesic Distance Computation

Tao, Jiong; Zhang, Jie; Deng, Bailin; Fang, Zheng; Peng, Yue; He, Ying

doi:10.1109/tpami.2019.2933209

Cited by 23 publications

(14 citation statements)

References 47 publications

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“…Most algorithms focus on computing SSAD on triangular meshes. Representative algorithms are wavefront propagation methods [2], [14], [15], [16], [17], [18], [19], [20], [21], partial differential equation (PDE) methods [3], [22], [23], [24], [25], [26], and graph-based methods [1], [4], [27].…”

Section: Related Workmentioning

confidence: 99%

GeodesicEmbedding (GE): A High-Dimensional Embedding Approach for Fast Geodesic Distance Queries

Xia

Zhang

Fang

et al. 2022

IEEE Trans. Visual. Comput. Graphics

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In this paper, we develop a novel method for fast geodesic distance queries. The key idea is to embed the mesh into a high-dimensional space, such that the Euclidean distance in the high-dimensional space can induce the geodesic distance in the original manifold surface. However, directly solving the high-dimensional embedding problem is not feasible due to the large number of variables and the fact that the embedding problem is highly nonlinear. We overcome the challenges with two novel ideas. First, instead of taking all vertices as variables, we embed only the saddle vertices, which greatly reduces the problem complexity. We then compute a local embedding for each non-saddle vertex. Second, to reduce the large approximation error resulting from the purely Euclidean embedding, we propose a cascaded optimization approach that repeatedly introduces additional embedding coordinates with a non-Euclidean function to reduce the approximation residual. Using the precomputation data, our approach can determine the geodesic distance between any two vertices in near-constant time. Computational testing results show that our method is more desirable than previous geodesic distance queries methods.

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Section: Related Workmentioning

confidence: 99%

GeodesicEmbedding (GE): A High-Dimensional Embedding Approach for Fast Geodesic Distance Queries

Xia

Zhang

Fang

et al. 2022

IEEE Trans. Visual. Comput. Graphics

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“…Rabinovich et al (2017) present a scalable approach for the optimization of flip-preventing energies for mesh parameterization, by iteratively minimizing a simple proxy energy instead of the original distortion energy. Tao et al (2018) propose a scalable heat method for computer geodesic distance, by reformulating the original heat method from Crane et al (2013) as an optimization problem for the distance gradient. The reformulation of LBC in this paper is similar to the gradient-based approach taken by Tao et al (2018), but with a non-smooth target function and a different set of constraints to enforce their defining properties.…”

Section: Improving Scalability Of Numerical Solversmentioning

confidence: 99%

“…Tao et al (2018) propose a scalable heat method for computer geodesic distance, by reformulating the original heat method from Crane et al (2013) as an optimization problem for the distance gradient. The reformulation of LBC in this paper is similar to the gradient-based approach taken by Tao et al (2018), but with a non-smooth target function and a different set of constraints to enforce their defining properties.…”

Section: Improving Scalability Of Numerical Solversmentioning

confidence: 99%

A fast numerical solver for local barycentric coordinates

Tao

Deng

Zhang

2019

Computer Aided Geometric Design

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The local barycentric coordinates (LBC), proposed in Zhang et al. (2014), demonstrate good locality and can be used for local control on function value interpolation and shape deformation. However, it has no closedform expression and must be computed by solving an optimization problem, which can be time-consuming especially for high-resolution models. In this paper, we propose a new technique to compute LBC efficiently. The new solver is developed based on two key insights. First, we prove that the non-negativity constraints in the original LBC formulation is not necessary, and can be removed without affecting the solution of the optimization problem. Furthermore, the removal of this constraint allows us to reformulate the computation of LBC as a convex constrained optimization for its gradients, followed by a fast integration to recover the coordinate values. The reformulated gradient optimization problem can be solved using ADMM, where each step is trivially parallelizable and does not involve global linear system solving, making it much more scalable and efficient than the original LBC solver. Numerical experiments verify the effectiveness of our technique on a large variety of models.

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“…However, the accuracy of the distance map computation is sensitive to the choice of a parameter. A parallel and scalable version of the Heat method was proposed by Tao et al [24]. Finally, Litman and Bronstein [25] proposed a method that also works on the spectral domain, called the Spectrometer.…”

Section: Related Workmentioning

confidence: 99%

“…In the case of CPU, the Cholmod library is more stable and we got a good result for the armadillo mesh. Recently, Tao et al [24] proposed a scalable version of the Heat Method, which has been tested only on CPU for large meshes. This method uses Gauss-Seidel iterations instead of solving the linear system using Cholesky decomposition.…”

Section: Performancementioning

confidence: 99%

A minimalistic approach for fast computation of geodesic distances on triangular meshes

Calla

Perez

Montenegro

2019

Computers & Graphics

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The computation of geodesic distances is an important research topic in Geometry Processing and 3D Shape Analysis as it is a basic component of many methods used in these areas. In this work, we present a minimalistic parallel algorithm based on front propagation to compute approximate geodesic distances on meshes. Our method is practical and simple to implement, and does not require any heavy pre-processing. The convergence of our algorithm depends on the number of discrete level sets around the source points from which distance information propagates. To appropriately implement our method on GPUs taking into account memory coalescence problems, we take advantage of a graph representation based on a breadth-first search traversal that works harmoniously with our parallel front propagation approach. We report experiments that show how our method scales with the size of the problem. We compare the mean error and processing time obtained by our method with such measures computed using other methods. Our method produces results in competitive times with almost the same accuracy, especially for large meshes. We also demonstrate its use for solving two classical geometry processing problems: the regular sampling problem and the Voronoi tessellation on meshes.

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Parallel and Scalable Heat Methods for Geodesic Distance Computation

Cited by 23 publications

References 47 publications

GeodesicEmbedding (GE): A High-Dimensional Embedding Approach for Fast Geodesic Distance Queries

GeodesicEmbedding (GE): A High-Dimensional Embedding Approach for Fast Geodesic Distance Queries

A fast numerical solver for local barycentric coordinates

A minimalistic approach for fast computation of geodesic distances on triangular meshes

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