Wim Abbeloos scite author profile

Wim Abbeloos

5Publications

19Citation Statements Received

73Citation Statements Given

How they've been cited

How they cite others

133

Affiliations

Toyota Motor Corporation (Switzerland), KU Leuven, Karel de Grote University College

Publications

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3D Object Discovery and Modeling Using Single RGB-D Images Containing Multiple Object Instances

Abbeloos

Ataer-Cansızoğlu

Caccamo

et al. 2017

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Unsupervised object modeling is important in robotics, especially for handling a large set of objects. We present a method for unsupervised 3D object discovery, reconstruction, and localization that exploits multiple instances of an identical object contained in a single RGB-D image. The proposed method does not rely on segmentation, scene knowledge, or user input, and thus is easily scalable. Our method aims to find recurrent patterns in a single RGB-D image by utilizing appearance and geometry of the salient regions. We extract keypoints and match them in pairs based on their descriptors. We then generate triplets of the keypoints matching with each other using several geometric criteria to minimize false matches. The relative poses of the matched triplets are computed and clustered to discover sets of triplet pairs with similar relative poses. Triplets belonging to the same set are likely to belong to the same object and are used to construct an initial object model. Detection of remaining instances with the initial object model using RANSAC allows to further expand and refine the model. The automatically generated object models are both compact and descriptive. We show quantitative and qualitative results on RGB-D images with various objects including some from the Amazon Picking Challenge. We also demonstrate the use of our method in an object picking scenario with a robotic arm.

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Point Pair Feature Based Object Detection for Random Bin Picking

Abbeloos

Goedemé

2016

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Abstract-Point pair features are a popular representation for free form 3D object detection and pose estimation. In this paper, their performance in an industrial random bin picking context is investigated. A new method to generate representative synthetic datasets is proposed. This allows to investigate the influence of a high degree of clutter and the presence of self similar features, which are typical to our application. We provide an overview of solutions proposed in literature and discuss their strengths and weaknesses. A simple heuristic method to drastically reduce the computational complexity is introduced, which results in improved robustness, speed and accuracy compared to the naive approach.

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MonoCInIS: Camera Independent Monocular 3D Object Detection using Instance Segmentation

Heylen¹,

Wolf²,

Dawagne³

et al. 2021

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Four-point-algorithm for the recovery of the pose of a one-dimensional camera with unknown focal length

et al. 2012

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The authors give an algorithm for recovering the centre and view direction of a one-dimensional camera with known principal point but unknown focal distance, by means of one view with four recognised landmarks. The involved algebra is reduced to solving a quadratic equation. This 4-point-method appears to be more robust than the existing 5-point-algorithm for locating a totally uncalibrated camera by means of chasles conics. On the other hand, the authors' method can offer an alternative for the triangulation method if the value of the focal length is unknown or unreliable (e.g. because of autozoom).

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Embedded line scan image sensors: The low cost alternative for high speed imaging

Wolputte

Abbeloos

Helsen

et al. 2015

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In this paper we propose a low-cost high-speed imaging line scan system. We replace an expensive industrial line scan camera and illumination with a custom-built set-up of cheap off-the-shelf components, yielding a measurement system with comparative quality while costing about 20 times less. We use a low-cost linear (1D) image sensor, cheap optics including a LED-based or LASER-based lighting and an embedded platform to process the images. A step-by-step method to design such a custom high speed imaging system and select proper components is proposed. Simulations allowing to predict the final image quality to be obtained by the set-up has been developed. Finally, we applied our method in a lab, closely representing the reallife cases. Our results shows that our simulations are very accurate and that our low-cost line scan set-up acquired image quality compared to the high-end commercial vision system, for a fraction of the price.

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Wim Abbeloos

3D Object Discovery and Modeling Using Single RGB-D Images Containing Multiple Object Instances

Point Pair Feature Based Object Detection for Random Bin Picking

MonoCInIS: Camera Independent Monocular 3D Object Detection using Instance Segmentation

Four-point-algorithm for the recovery of the pose of a one-dimensional camera with unknown focal length

Embedded line scan image sensors: The low cost alternative for high speed imaging

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