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2019


Towards Geometric Understanding of Motion
Towards Geometric Understanding of Motion

Ranjan, A.

University of Tübingen, December 2019 (phdthesis)

Abstract

The motion of the world is inherently dependent on the spatial structure of the world and its geometry. Therefore, classical optical flow methods try to model this geometry to solve for the motion. However, recent deep learning methods take a completely different approach. They try to predict optical flow by learning from labelled data. Although deep networks have shown state-of-the-art performance on classification problems in computer vision, they have not been as effective in solving optical flow. The key reason is that deep learning methods do not explicitly model the structure of the world in a neural network, and instead expect the network to learn about the structure from data. We hypothesize that it is difficult for a network to learn about motion without any constraint on the structure of the world. Therefore, we explore several approaches to explicitly model the geometry of the world and its spatial structure in deep neural networks.

The spatial structure in images can be captured by representing it at multiple scales. To represent multiple scales of images in deep neural nets, we introduce a Spatial Pyramid Network (SpyNet). Such a network can leverage global information for estimating large motions and local information for estimating small motions. We show that SpyNet significantly improves over previous optical flow networks while also being the smallest and fastest neural network for motion estimation. SPyNet achieves a 97% reduction in model parameters over previous methods and is more accurate.

The spatial structure of the world extends to people and their motion. Humans have a very well-defined structure, and this information is useful in estimating optical flow for humans. To leverage this information, we create a synthetic dataset for human optical flow using a statistical human body model and motion capture sequences. We use this dataset to train deep networks and see significant improvement in the ability of the networks to estimate human optical flow.

The structure and geometry of the world affects the motion. Therefore, learning about the structure of the scene together with the motion can benefit both problems. To facilitate this, we introduce Competitive Collaboration, where several neural networks are constrained by geometry and can jointly learn about structure and motion in the scene without any labels. To this end, we show that jointly learning single view depth prediction, camera motion, optical flow and motion segmentation using Competitive Collaboration achieves state-of-the-art results among unsupervised approaches.

Our findings provide support for our hypothesis that explicit constraints on structure and geometry of the world lead to better methods for motion estimation.

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PhD Thesis [BibTex]

2019


PhD Thesis [BibTex]


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Ferromagnetic colloids in liquid crystal solvents

Zarubin, G.

Universität Stuttgart, Stuttgart, 2019 (phdthesis)

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link (url) DOI [BibTex]

link (url) DOI [BibTex]


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Fluctuating interface with a pinning potential

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Universität Stuttgart, Stuttgart, 2019 (mastersthesis)

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Universität Stuttgart, Stuttgart, 2019 (phdthesis)

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link (url) DOI [BibTex]

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Das Tier als Modell für Roboter, und Roboter als Modell für Tiere
Das Tier als Modell für Roboter, und Roboter als Modell für Tiere

Badri-Spröwitz, A.

In pages: 167-175, Springer, 2019 (incollection)

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DOI [BibTex]

DOI [BibTex]

2010


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Nanofluidics of thin liquid films

Rauscher, M., Dietrich, S.

In Handbook of Nanophysics, Principles and Methods, 1, pages: 11-1-11-23, Handbook of Nanophysics, CRC Press, Boca Raton, 2010 (incollection)

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2010


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Almenar Egea, L.

Universität Stuttgart, Stuttgart, 2010 (phdthesis)

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Maier, D.

Universität Stuttgart, Stuttgart, 2010 (mastersthesis)

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[BibTex]

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Untersuchung der kritischen Adsorption an kolloidalen Teilchen mit Hilfe von Streutechniken

Slupina, C.

Universität Stuttgart, Stuttgart, 2010 (mastersthesis)

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[BibTex]

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Dynamics of nanoscopic capillary waves

Mecke, K., Falk, K., Rauscher, M.

In Nonlinear Dynamics of Nanosystems, pages: 121-142, Wiley-VCH, Berlin, 2010 (incollection)

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DOI [BibTex]

DOI [BibTex]


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Critical Casimir interaction between a cylindrical particle and a chemically structured substrate

Labbe-Laurent, M.

Universität Stuttgart, Stuttgart, 2010 (mastersthesis)

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[BibTex]

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Capillary interactions between colloidal particles at curved fluid interfaces

Guzowski, J.

Universität Stuttgart, Stuttgart, 2010 (phdthesis)

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link (url) [BibTex]

link (url) [BibTex]