Michael Strecke scite author profile

We present a fully convolutional autoencoder for light fields, which jointly encodes stacks of horizontal and vertical epipolar plane images through a deep network of residual layers. The complex structure of the light field is thus reduced to a comparatively low-dimensional representation, which can be decoded in a variety of ways. The different pathways of upconvolution we currently support are for disparity estimation and separation of the lightfield into diffuse and specular intrinsic components. The key idea is that we can jointly perform unsupervised training for the autoencoder path of the network, and supervised training for the other decoders. This way, we find features which are both tailored to the respective tasks and generalize well to datasets for which only example light fields are available. We provide an extensive evaluation on synthetic light field data, and show that the network yields good results on previously unseen real world data captured by a Lytro Illum camera and various gantries.

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EM-Fusion: Dynamic Object-Level SLAM With Probabilistic Data Association

Strecke

Stueckler

2019

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The majority of approaches for acquiring dense 3D environment maps with RGB-D cameras assumes static environments or rejects moving objects as outliers. The representation and tracking of moving objects, however, has significant potential for applications in robotics or augmented reality. In this paper, we propose a novel approach to dynamic SLAM with dense object-level representations. We represent rigid objects in local volumetric signed distance function (SDF) maps, and formulate multi-object tracking as direct alignment of RGB-D images with the SDF representations. Our main novelty is a probabilistic formulation which naturally leads to strategies for data association and occlusion handling. We analyze our approach in experiments and demonstrate that our approach compares favorably with the state-of-the-art methods in terms of robustness and accuracy.

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Accurate Depth and Normal Maps from Occlusion-Aware Focal Stack Symmetry

Strecke

Alperovich

Goldluecke

2017

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A Taxonomy and Evaluation of Dense Light Field Depth Estimation Algorithms

Johannsen

Honauer

Goldluecke

et al. 2017

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Shadow and Specularity Priors for Intrinsic Light Field Decomposition

Alperovich

Johannsen

Strecke

et al. 2018

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Michael Strecke

Light Field Intrinsics with a Deep Encoder-Decoder Network

EM-Fusion: Dynamic Object-Level SLAM With Probabilistic Data Association

Accurate Depth and Normal Maps from Occlusion-Aware Focal Stack Symmetry

A Taxonomy and Evaluation of Dense Light Field Depth Estimation Algorithms

Shadow and Specularity Priors for Intrinsic Light Field Decomposition

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