Probabilistic Permutation Synchronization Using the Riemannian Structure of the Birkhoff Polytope

Birdal, Tolga; Şimşekli, Umut

doi:10.1109/cvpr.2019.01136

Cited by 29 publications

(36 citation statements)

References 69 publications

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“…Taking a step further, other modern methods make use of the global cycle-consistency and optimize only over the poses starting from an initial set of pairwise maps. This efficient approach is known as synchronization [10,61,2,56,3,5,43,69,7,35]. Global structurefrom-motion [17,70] aims to synchronize the observed relative motions by decomposing rotation, translation and scale components.…”

Section: Related Workmentioning

confidence: 99%

Learning Multiview 3D Point Cloud Registration

Gojčič

Zhou

Wegner

et al. 2020

2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)

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144

107

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We present a novel, end-to-end learnable, multiview 3D point cloud registration algorithm. Registration of multiple scans typically follows a two-stage pipeline: the initial pairwise alignment and the globally consistent refinement. The former is often ambiguous due to the low overlap of neighboring point clouds, symmetries and repetitive scene parts. Therefore, the latter global refinement aims at establishing the cyclic consistency across multiple scans and helps in resolving the ambiguous cases. In this paper we propose, to the best of our knowledge, the first end-to-end algorithm for joint learning of both parts of this two-stage problem. Experimental evaluation on well accepted benchmark datasets shows that our approach outperforms the state-of-the-art by a significant margin, while being end-toend trainable and computationally less costly. Moreover, we present detailed analysis and an ablation study that validate the novel components of our approach. The source code and pretrained models are publicly available under https: //github.com/zgojcic/3D_multiview_reg.

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Section: Related Workmentioning

confidence: 99%

Learning Multiview 3D Point Cloud Registration

Gojčič

Zhou

Wegner

et al. 2020

2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)

Self Cite

144

107

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“…States are usually represented by elements of a group, such as the set of permutations or the set of Euclidean transformations. The former can represent local labels of a set of features, as it occurs in multi-view matching applications (Pachauri et al 2013;Birdal and Simsekli 2019). The latter can represent camera reference frames (e.g., in the context of structure from motion (Govindu 2004;Hartley et al 2011Hartley et al , 2013 or pose graph optimization (Carlone et al 2015;Rosen et al 2017)), or local coordinates of 3D point clouds when dealing with 3D registration (Torsello et al 2011;Bernard et al 2015;Arrigoni et al 2016).…”

Section: Synchronizationmentioning

confidence: 99%

Multi-frame Motion Segmentation by Combining Two-Frame Results

2022

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In this paper we consider the motion segmentation problem on sparse and unstructured datasets involving rigid motions, motivated by multibody structure from motion. In particular, we assume only two-frame correspondences as input without prior knowledge about trajectories. Inspired by the success of synchronization methods, we address this problem by introducing a two-stage approach: first, motion segmentation is addressed on image pairs independently; then, two-frame results are combined in a robust way to compute the final multi-frame segmentation. Our synthetic and real experiments demonstrate that the proposed approach is very effective in reducing the errors among two-frame results and it can cope with a large amount of mismatches. Moreover, our method can be profitably used to build a multibody structure from motion pipeline.

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“…( 7), or its Riemannian version Eq. ( 9) as done repeatedly in the literature, we propose to characterize the empirical posterior distribution related to the energy similar to [4]. We formulate the functional map synchronization problem in a probabilistic fashion: We treat the pairwise functional maps as observed random variables and the absolute ones as latent random variables.…”

Section: Probabilistic Synchronization Of Functional Mapsmentioning

confidence: 99%

“…the negative log-posterior is non-convex) and any algorithm that aims to solve one of these problems should be able to operate in the particular manifold of this problem. To this end, we adopt an algorithmically simple yet effective algorithm, the Riemannian Langevin Monte Carlo as explained in [4,13].…”

Section: Probabilistic Synchronization Of Functional Mapsmentioning

confidence: 99%

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Riemannian Functional Map Synchronization for Probabilistic Partial Correspondence in Shape Networks

Huq¹,

Dey²,

Sahra³

et al. 2021

Preprint

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Functional maps are efficient representations of shape correspondences, that provide matching of real-valued functions between pairs of shapes. Functional maps can be modelled as elements of the Lie group SO(n) for nearly isometric shapes. Synchronization can subsequently be employed to enforce cycle consistency between functional maps computed on a set of shapes, hereby enhancing the accuracy of the individual maps. There is an interest in developing synchronization methods that respect the geometric structure of SO(n), while introducing a probabilistic framework to quantify the uncertainty associated with the synchronization results. This paper introduces a Bayesian probabilistic inference framework on SO(n) for Riemannian synchronization of functional maps, performs a maximum-a-posteriori estimation of functional maps through synchronization and further deploys a Riemannian Markov-Chain Monte Carlo sampler for uncertainty quantification. Our experiments demonstrate that constraining the synchronization on the Riemannian manifold SO(n) improves the estimation of the functional maps, while our Riemannian MCMC sampler provides for the first time an uncertainty quantification of the results.

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Probabilistic Permutation Synchronization Using the Riemannian Structure of the Birkhoff Polytope

Cited by 29 publications

References 69 publications

Learning Multiview 3D Point Cloud Registration

Learning Multiview 3D Point Cloud Registration

Multi-frame Motion Segmentation by Combining Two-Frame Results

Riemannian Functional Map Synchronization for Probabilistic Partial Correspondence in Shape Networks

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