2017
DOI: 10.1111/cgf.13254
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Deblurring and Denoising of Maps between Shapes

Abstract: Shape correspondence is an important and challenging problem in geometry processing. Generalized map representations, such as functional maps, have been recently suggested as an approach for handling difficult mapping problems, such as partial matching and matching shapes with high genus, within a generic framework. While this idea was shown to be useful in various scenarios, such maps only provide low frequency information on the correspondence. In many applications, such as texture transfer and shape interpo… Show more

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Cited by 77 publications
(89 citation statements)
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“…We compare our results with the initial map computed using HOT and with the shape correspondence method that was recently suggested by Manded et al [MCSK∗17] (VMTP). Additionally, we compare with two other methods that improve input correspondences, where we use the same initialization as our method (HOT): one method is based on functional maps [EBC17] (DDM) and another optimizes the reversible harmonic energy [ESBC19] (RHM). The quantitative comparison is shown in Fig.…”
Section: Resultsmentioning
confidence: 99%
“…We compare our results with the initial map computed using HOT and with the shape correspondence method that was recently suggested by Manded et al [MCSK∗17] (VMTP). Additionally, we compare with two other methods that improve input correspondences, where we use the same initialization as our method (HOT): one method is based on functional maps [EBC17] (DDM) and another optimizes the reversible harmonic energy [ESBC19] (RHM). The quantitative comparison is shown in Fig.…”
Section: Resultsmentioning
confidence: 99%
“…Shape matching is a long‐standing problem in shape analysis [vKZHCO11]. It is often done explicitly, by deforming a source shape to a target [RL01, BR07, LSP08, HAWG08, ZSCO*08], or implicitly, by mapping points [KLF11, CK15, OMMG10, BBK06] or functions [OBCS*12, RPWO18, EBC17] on one shape to another. The deformation‐based methods typically aim to minimize the amount of distortion introduced by the deformation, and the mapping‐based approaches often assume that shapes to be near‐isometric.…”
Section: Related Workmentioning
confidence: 99%
“…Functional Maps. Our approach fits within the functional map framework, which was originally introduced in [OBCS*12] for solving non‐rigid shape matching problems, and extended significantly in follow‐up works, including [KBB*13, ADK16, KBBV15, RCB*17, EBC17, BDK17] among many others (see also [OCB*17] for an overview). The key observation in these techniques is that it is often easier to estimate correspondences between real‐valued functions, rather than points on the shapes.…”
Section: Related Workmentioning
confidence: 99%
“…As mentioned above, the most common approach consists of penalizing the failure of the unknown functional map to commute with the Laplace‐Beltrami operators, which can be written as: where Δ 1 and Δ 2 are the Laplace‐Beltrami operators of the two shapes expressed in the respective bases. Here, and throughout the rest of our paper, unless stated otherwise || · || denotes the matrix Frobenius norm. Convert the functional map C to a point‐to‐point map, for example using an iterative approach, such as the Iterative Closest Point (ICP) in the spectral embedding, or using other more advanced techniques [RMC15, EBC17]. …”
Section: Introductionmentioning
confidence: 99%