A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Instance Segmentation of Industrial Point Cloud Data
The challenge that this paper addresses is how to efficiently minimize the cost and manual labor for automatically generating object oriented geometric digital twins (gDTs) of industrial facilities, so that the benefits provide even more value compared to the initial investment to generate these models. Our previous work achieved the current state-of-the-art class segmentation performance (75% average accuracy per point and average area under the ROC curve, AUC, 90% in the CLOI dataset classes) and directly produces labelled point clusters of the most important to model objects (CLOI classes) from laser scanned industrial data. CLOI stands for C-shapes, L-shapes, O-shapes, I-shapes and their combinations. However, the problem of automated segmentation of individual instances that can then be used to fit geometric shapes remains unsolved. We argue that the use of instance segmentation algorithms has the theoretical potential to provide the output needed for the generation of gDTs. We solve instance segmentation in this paper through (1) using a CLOI-Instance graph connectivity algorithm that segments the point clusters of an object class into instances, and (2) boundary segmentation of points that improves Step 1. Our method was tested on the CLOI benchmark dataset and segmented instances with 76.25% average precision and 70% average recall per point among all classes. This proved that it is the first to automatically segment industrial point cloud shapes with no prior knowledge other than the class point label and is the bedrock for efficient gDT generation in cluttered industrial point clouds.
Instance Segmentation of Industrial Point Cloud Data
The challenge that this paper addresses is how to efficiently minimize the cost and manual labor for automatically generating object oriented geometric digital twins (gDTs) of industrial facilities, so that the benefits provide even more value compared to the initial investment to generate these models. Our previous work achieved the current state-of-the-art class segmentation performance (75% average accuracy per point and average area under the ROC curve, AUC, 90% in the CLOI dataset classes) and directly produces labelled point clusters of the most important to model objects (CLOI classes) from laser scanned industrial data. CLOI stands for C-shapes, L-shapes, O-shapes, I-shapes and their combinations. However, the problem of automated segmentation of individual instances that can then be used to fit geometric shapes remains unsolved. We argue that the use of instance segmentation algorithms has the theoretical potential to provide the output needed for the generation of gDTs. We solve instance segmentation in this paper through (1) using a CLOI-Instance graph connectivity algorithm that segments the point clusters of an object class into instances, and (2) boundary segmentation of points that improves Step 1. Our method was tested on the CLOI benchmark dataset and segmented instances with 76.25% average precision and 70% average recall per point among all classes. This proved that it is the first to automatically segment industrial point cloud shapes with no prior knowledge other than the class point label and is the bedrock for efficient gDT generation in cluttered industrial point clouds.
Instance Segmentation of Industrial Point Cloud Data
Agapaki, Eva (author) / Brilakis, Ioannis (author)
2021-08-23
Article (Journal)
Electronic Resource
Unknown
Octree-based segmentation for terrestrial LiDAR point cloud data in industrial applications
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