Adam R. Kosiorek scite author profile

An object can be seen as a geometrically organized set of interrelated parts. A system that makes explicit use of these geometric relationships to recognize objects should be naturally robust to changes in viewpoint, because the intrinsic geometric relationships are viewpoint-invariant. We describe an unsupervised version of capsule networks, in which a neural encoder, which looks at all of the parts, is used to infer the presence and poses of object capsules. The encoder is trained by backpropagating through a decoder, which predicts the pose of each already discovered part using a mixture of pose predictions. The parts are discovered directly from an image, in a similar manner, by using a neural encoder, which infers parts and their affine transformations. The corresponding decoder models each image pixel as a mixture of predictions made by affine-transformed parts. We learn object-and their part-capsules on unlabeled data, and then cluster the vectors of presences of object capsules. When told the names of these clusters, we achieve state-of-the-art results for unsupervised classification on SVHN (55%) and near state-of-the-art on MNIST (98.5%). * This work was done during an internship at Google Brain. 2 This may explain why accessing perceptual knowledge about objects, when they are not visible, requires creating a mental image of the object with a specific viewpoint.Preprint. Under review.

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Adversarial Masking for Self-Supervised Learning

Shi¹,

Siddharth²,

Torr³

et al. 2022

Preprint

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We propose ADIOS, a masked image modeling (MIM) framework for self-supervised learning, which simultaneously learns a masking function and an image encoder using an adversarial objective. The image encoder is trained to minimise the distance between representations of the original and that of a masked image. The masking function, conversely, aims at maximising this distance. ADIOS consistently improves on state-ofthe-art self-supervised learning (SSL) methods on a variety of tasks and datasets-including classification on ImageNet100 and STL10, transfer learning on CIFAR10/100, Flowers102 and iNaturalist, as well as robustness evaluated on the backgrounds challenge (Xiao et al., 2021)-while generating semantically meaningful masks. Unlike modern MIM models such as MAE, BEiT and iBOT, ADIOS does not rely on the image-patch tokenisation construction of Vision Transformers, and can be implemented with convolutional backbones. We further demonstrate that the masks learned by ADIOS are more effective in improving representation learning of SSL methods than masking schemes used in popular MIM models.

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End-to-end Recurrent Multi-Object Tracking and Trajectory Prediction with Relational Reasoning

Fuchs¹,

Kosiorek²,

Li³

et al. 2019

Preprint

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Relational reasoning-the ability to model interactions and relations between objectsis valuable for robust multi-object tracking and pivotal for trajectory prediction. In this paper, we propose MOHART, a class-agnostic, end-to-end multi-object tracking and trajectory prediction algorithm, which explicitly accounts for permutation invariance in its relational reasoning. We explore a number of permutation invariant architectures and show that multi-headed self-attention outperforms the provided baselines and better accounts for complex physical interactions in a challenging toy experiment. We show on three real-world tracking datasets that adding relational reasoning capabilities in this way increases the tracking and trajectory prediction performance, particularly in the presence of ego-motion, occlusions, crowded scenes, and faulty sensor inputs. To the best of our knowledge, MOHART is the first fully end-to-end multi-object tracking from vision approach applied to real-world data reported in the literature.

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Laser: Latent Set Representations for 3D Generative Modeling

Moreno¹,

Kosiorek²,

Strathmann³

et al. 2023

Preprint

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Neural Radiance Field (NeRF) provides unparalleled fidelity of novel view synthesis-rendering a 3D scene from an arbitrary viewpoint. NeRF requires training on a large number of views that fully cover a scene, which limits its applicability. While these issues can be addressed by learning a prior over scenes in various forms, previous approaches have been either applied to overly simple scenes or struggling to render unobserved parts. We introduce Latent Set Representations for NeRF-VAE (LASER-NV)-a generative model which achieves high modelling capacity, and which is based on a set-valued latent representation modelled by normalizing flows. Similarly to previous amortized approaches, LASER-NV learns structure from multiple scenes and is capable of fast, feed-forward inference from few views. To encourage higher rendering fidelity and consistency with observed views, LASER-NV further incorporates a geometry-informed attention mechanism over the observed views. LASER-NV further produces diverse and plausible completions of occluded parts of a scene while remaining consistent with observations. LASER-NV shows state-of-the-art novel-view synthesis quality when evaluated on ShapeNet and on a novel simulated City dataset, which features high uncertainty in the unobserved regions of the scene. See laser-nv-paper.github.io for video results, code and data.

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Adam R. Kosiorek

Tighter Variational Bounds are Not Necessarily Better

Stacked Capsule Autoencoders

Adversarial Masking for Self-Supervised Learning

End-to-end Recurrent Multi-Object Tracking and Trajectory Prediction with Relational Reasoning

Laser: Latent Set Representations for 3D Generative Modeling

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