Global Medical Shape Analysis Using the Volumetric Laplace Spectrum

Barchetti, Ugo; Bucciero, Alberto; Mainetti, Luca; Sabato, Stefano Santo

doi:10.1109/cw.2007.42

Cited by 27 publications

(27 citation statements)

References 20 publications

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“…The Reeb graph can also be helpful to improve this approach for surfaces of higher genus by incorporating the pairs of essential homology classes to include handles (extended persistence). The presented method for shape segmentation can also be extended to 3D solids using the 3D Laplacian on tetrahedra or voxel representations as described in [23,26].…”

Section: Resultsmentioning

confidence: 99%

“…The higher order approach used here is already described in [53,23,36] for triangle meshes, NURBS patches, other parametrized surfaces and (parametrized) 3D tetrahedra meshes and in [26] for voxels. Here we will explain the computation for the specific case of piecewise flat triangulations and give closed formulas in the Appendix.…”

Section: Computation Of Eigenfunctionsmentioning

confidence: 99%

“…Note that [22] employs level sets of eigenfunctions to implictly construct correspondence of brain structures for statistical shape analysis. Other work employing spectral entities of the Laplace Beltrami operator includes retrieval [23,24], medical shape analysis [25][26][27]22], filtering/smoothing [28][29][30] of which specifically [28] mentions the use of zero level sets of specific eigenfunctions for mesh segmentation. This idea is later analyzed in more detail in [16], where also a comparison of different common discrete Laplace Beltrami operators is given.…”

Section: Related Workmentioning

confidence: 99%

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Hierarchical Shape Segmentation and Registration via Topological Features of Laplace-Beltrami Eigenfunctions

Reuter

2009

Int J Comput Vis

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153

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This work introduces a method to hierarchically segment articulated shapes into meaningful parts and to register these parts across populations of nearisometric shapes (e.g. head, arms, legs and fingers of humans in different body postures). The method exploits the isometry invariance of eigenfunctions of the Laplace-Beltrami operator and uses topological features (level sets at important saddles) for the segmentation. Concepts from persistent homology are employed for a hierarchical representation, for the elimination of topological noise and for the comparison of eigenfunctions. The obtained parts can be registered via their spectral embedding across a population of near isometric shapes. This work also presents the highly accurate computation of eigenfunctions and eigenvalues with cubic finite elements on triangle meshes and discusses the construction of persistence diagrams from the MorseSmale complex as well as the relation to size functions.

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Section: Resultsmentioning

confidence: 99%

Section: Computation Of Eigenfunctionsmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

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Hierarchical Shape Segmentation and Registration via Topological Features of Laplace-Beltrami Eigenfunctions

Reuter

2009

Int J Comput Vis

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153

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“…This was done first for triangle surface meshes with a linear finite element method (FEM) in [20], for parametrized surfaces, triangle and tetrahedra meshes using higher order FEM in [48,49] and for voxel data in [47]. The discrete setting (6) with linear finite elements is equivalent to the generalized eigenvalue problem…”

Section: Discrete Geometric Laplaciansmentioning

confidence: 99%

Discrete Laplace–Beltrami operators for shape analysis and segmentation

Reuter

Biasotti

Giorgi

et al. 2009

Computers & Graphics

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266

184

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Shape analysis plays a pivotal role in a large number of applications, ranging from traditional geometry processing to more recent 3D content management. In this scenario, spectral methods are extremely promising as they provide a natural library of tools for shape analysis, intrinsically defined by the shape itself. In particular, the eigenfunctions of the Laplace-Beltrami operator yield a set of real valued functions that provide interesting insights in the structure and morphology of the shape. In this paper, we first analyze different discretizations of the Laplace-Beltrami operator (geometric Laplacians, linear and cubic FEM operators) in terms of the correctness of their eigenfunctions with respect to the continuous case. We then present the family of segmentations induced by the nodal sets of the eigenfunctions, discussing its meaningfulness for shape understanding.

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“…The Laplace operator has previously been used for mesh smoothing and regularization [12], for surface editing [13], and for 3D mesh fitting [14]. Furthermore, the spectrum of the Laplace operator has been used for mesh processing in a similar way to the Fourier transforms of images [15], and for shape matching and dissimilarity computation of volumetric data [16] and of triangle meshes [17]. Baran et al [18] used differential coordinates over local connected patches of a mesh to define a shape representation that is used to transfer mesh deformations from one character to another one while preserving the semantic meaning.…”

Section: Related Workmentioning

confidence: 99%

Posture-invariant statistical shape analysis using Laplace operator

Wuhrer

Shu

2012

Computers & Graphics

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Statistical shape analysis is a tool that allows to quantify the shape variability of a population of shapes. Traditional tools to perform statistical shape analysis compute variations that reflect both shape and posture changes simultaneously. In many applications, such as ergonomic design applications, we are only interested in shape variations. With traditional tools, it is not straightforward to separate shape and posture variations. To overcome this problem, we propose an approach to perform statistical shape analysis in a posture-invariant way. The approach is based on a local representation that is obtained using the Laplace operator.

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Global Medical Shape Analysis Using the Volumetric Laplace Spectrum

Cited by 27 publications

References 20 publications

Hierarchical Shape Segmentation and Registration via Topological Features of Laplace-Beltrami Eigenfunctions

Hierarchical Shape Segmentation and Registration via Topological Features of Laplace-Beltrami Eigenfunctions

Discrete Laplace–Beltrami operators for shape analysis and segmentation

Posture-invariant statistical shape analysis using Laplace operator

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