Unsupervised Adversarial Learning of 3D Human Pose from 2D Joint Locations

Kudo, Yuta; Ogaki, Keisuke; Matsui, Yusuke; Odagiri, Yuri

doi:10.48550/arxiv.1803.08244

Cited by 17 publications

(19 citation statements)

References 29 publications

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“…Detected 2D GT 2D Iskakov et al [18] 20.8 -Remelli et al [43] 30.2 -Kadkhodamohammadi et al [21] 49.1 -Tome et al [49] 52.8 -Pavlakos et al [41] 56.9 -Multi-view Martinez [35] 57.0 -Rhodin et al [44] 51.6 -Kocabas et al [25] 45.04 -Kocabas et al (SS w/o R) [25] 70.67 -PRN [40] 124.5 86.4 RepNet [50] 65.1 38.2 Iqbal et al [17] 69.1 -Pose-GAN [29] 173.2 130.9 Deep NRSfM [27] -104.2 C3DPO [37] 153.0 95.6 MV NRSfM (Ours) 45.2 30.2…”

Section: Methodsmentioning

confidence: 99%

High Fidelity 3D Reconstructions with Limited Physical Views

Dabhi¹,

Wang²,

Saluja³

et al. 2021

Preprint

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Multi-view triangulation is the gold standard for 3D reconstruction from 2D correspondences given known calibration and sufficient views. However in practice, expensive multi-view setups -involving tens sometimes hundreds of cameras -are required in order to obtain the high fidelity 3D reconstructions necessary for many modern applications. In this paper we present a novel approach that leverages recent advances in 2D-3D lifting using neural shape priors while also enforcing multi-view equivariance. We show how our method can achieve comparable fidelity to expensive calibrated multi-view rigs using a limited (2-3) number of uncalibrated camera views.

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Section: Methodsmentioning

confidence: 99%

High Fidelity 3D Reconstructions with Limited Physical Views

Dabhi¹,

Wang²,

Saluja³

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…The idea is that the learned 3D model can be used to generate arbitrary views of an object, such that the discriminator network can provide supervisory signal to learn the geometry by telling whether the generated views are plausible or not. Examples include the works of [24,2], PlatonicGAN [16], HoloGAN [37], BlockGAN [38], Shelf-supervised learning [64] and GRAF [50]. This type of approach does not require information about specific viewpoints, but does require to know the distribution of viewpoints in the training data (as the discriminator is sensitive to that).…”

Section: Related Workmentioning

confidence: 99%

DOVE: Learning Deformable 3D Objects by Watching Videos

Wu¹,

Jakab²,

Rupprecht³

et al. 2021

Preprint

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Learning deformable 3D objects from 2D images is an extremely ill-posed problem. Existing methods rely on explicit supervision to establish multi-view correspondences, such as template shape models and keypoint annotations, which restricts their applicability on objects "in the wild". In this paper, we propose to use monocular videos, which naturally provide correspondences across time, allowing us to learn 3D shapes of deformable object categories without explicit keypoints or template shapes. Specifically, we present DOVE, which learns to predict 3D canonical shape, deformation, viewpoint and texture from a single 2D image of a bird, given a bird video collection as well as automatically obtained silhouettes and optical flows as training data. Our method reconstructs temporally consistent 3D shape and deformation, which allows us to animate and re-render the bird from arbitrary viewpoints from a single image. IntroductionRecently, with the adoption of machine learning, reconstructing 3D shapes from 2D images has advanced considerably. While this task traditionally requires establishing correspondences between multiple views [13], learning-based approaches have demonstrated the possibility of inferring 3D shapes from a single image, by learning priors for a specific object category [

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“…Instead of using classical NRSf M priors, recent works explore the use of deeper constraints. Generative Adversarial Networks (GANs) [14] are used to enforce realism of 2D reprojections across novel viewpoints [9,39,11,23]. These methods are only applicable for large datasets due to the requirement of learning GANs.…”

Section: Related Workmentioning

confidence: 99%

“…SH pts. [32] Pose-GAN [23] 130.9 173.2 C3DPO [32] 95.6 153.0 PRN [33] 86.4 124.5 PAUL 88.3 132.5 sion from 2 to 12 on different datasets. To account for the stochastic behavior due to network initialization and gradient descent on small datasets, we run the methods 10 times and visualize with average accuracy (solid lines) together with standard deviation (colored area).…”

Section: Nrsf M Experimentsmentioning

confidence: 99%

PAUL: Procrustean Autoencoder for Unsupervised Lifting

Wang

Lucey

2021

Preprint

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Recent success in casting Non-rigid Structure from Motion (NRSfM) as an unsupervised deep learning problem has raised fundamental questions about what novelty in NRSfM prior could the deep learning offer. In this paper we advocate for a 3D deep auto-encoder framework to be used explicitly as the NRSfM prior. The framework is unique as: (i) it learns the 3D auto-encoder weights solely from 2D projected measurements, and (ii) it is Procrustean in that it jointly resolves the unknown rigid pose for each shape instance. We refer to this architecture as a Procustean Autoencoder for Unsupervised Lifting (PAUL), and demonstrate state-of-the-art performance across a number of benchmarks in comparison to recent innovations such as Deep NRSfM [21] and C3PDO [32].

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Unsupervised Adversarial Learning of 3D Human Pose from 2D Joint Locations

Cited by 17 publications

References 29 publications

High Fidelity 3D Reconstructions with Limited Physical Views

High Fidelity 3D Reconstructions with Limited Physical Views

DOVE: Learning Deformable 3D Objects by Watching Videos

PAUL: Procrustean Autoencoder for Unsupervised Lifting

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