1,277 research outputs found
Semantically Informed Multiview Surface Refinement
We present a method to jointly refine the geometry and semantic segmentation
of 3D surface meshes. Our method alternates between updating the shape and the
semantic labels. In the geometry refinement step, the mesh is deformed with
variational energy minimization, such that it simultaneously maximizes
photo-consistency and the compatibility of the semantic segmentations across a
set of calibrated images. Label-specific shape priors account for interactions
between the geometry and the semantic labels in 3D. In the semantic
segmentation step, the labels on the mesh are updated with MRF inference, such
that they are compatible with the semantic segmentations in the input images.
Also, this step includes prior assumptions about the surface shape of different
semantic classes. The priors induce a tight coupling, where semantic
information influences the shape update and vice versa. Specifically, we
introduce priors that favor (i) adaptive smoothing, depending on the class
label; (ii) straightness of class boundaries; and (iii) semantic labels that
are consistent with the surface orientation. The novel mesh-based
reconstruction is evaluated in a series of experiments with real and synthetic
data. We compare both to state-of-the-art, voxel-based semantic 3D
reconstruction, and to purely geometric mesh refinement, and demonstrate that
the proposed scheme yields improved 3D geometry as well as an improved semantic
segmentation
A 3D INDOOR-OUTDOOR BENCHMARK DATASET FOR LoD3 BUILDING POINT CLOUD SEMANTIC SEGMENTATION
Deep learning (DL) algorithms require high quality training samples as well as accurate and thorough annotations to work effectively. Up until now a limited number of datasets are available to train DL techniques for semantic segmentation of 3D building point clouds, except a few ones focusing on specific categories of constructions (e.g., cultural heritage buildings). This paper presents a new 3D Indoor/Outdoor building dataset (BIO dataset), which is aimed to provide a highly accurate, detailed, and comprehensive dataset to be used for applications related to sematic classification of buildings based on point clouds and meshes. This benchmark dataset contains 100 building models generated from existing polygonal models and belonging to different categories. These include commercial buildings, residential houses, industrial and institutional buildings. Structural elements of buildings are annotated into 11 semantic categories, following standards from IFC and CityGML. To verify the applicability of the BIO dataset for the semantic segmentation task, it has been successfully tested by using one machine learning technique and four different DL algorithms
Semantic Instance Annotation of Street Scenes by 3D to 2D Label Transfer
Semantic annotations are vital for training models for object recognition,
semantic segmentation or scene understanding. Unfortunately, pixelwise
annotation of images at very large scale is labor-intensive and only little
labeled data is available, particularly at instance level and for street
scenes. In this paper, we propose to tackle this problem by lifting the
semantic instance labeling task from 2D into 3D. Given reconstructions from
stereo or laser data, we annotate static 3D scene elements with rough bounding
primitives and develop a model which transfers this information into the image
domain. We leverage our method to obtain 2D labels for a novel suburban video
dataset which we have collected, resulting in 400k semantic and instance image
annotations. A comparison of our method to state-of-the-art label transfer
baselines reveals that 3D information enables more efficient annotation while
at the same time resulting in improved accuracy and time-coherent labels.Comment: 10 pages in Conference on Computer Vision and Pattern Recognition
(CVPR), 201
Semantic Mapping of Road Scenes
The problem of understanding road scenes has been on the fore-front in the computer vision community
for the last couple of years. This enables autonomous systems to navigate and understand
the surroundings in which it operates. It involves reconstructing the scene and estimating the objects
present in it, such as ‘vehicles’, ‘road’, ‘pavements’ and ‘buildings’. This thesis focusses on these
aspects and proposes solutions to address them.
First, we propose a solution to generate a dense semantic map from multiple street-level images.
This map can be imagined as the bird’s eye view of the region with associated semantic labels for
ten’s of kilometres of street level data. We generate the overhead semantic view from street level
images. This is in contrast to existing approaches using satellite/overhead imagery for classification
of urban region, allowing us to produce a detailed semantic map for a large scale urban area. Then
we describe a method to perform large scale dense 3D reconstruction of road scenes with associated
semantic labels. Our method fuses the depth-maps in an online fashion, generated from the
stereo pairs across time into a global 3D volume, in order to accommodate arbitrarily long image
sequences. The object class labels estimated from the street level stereo image sequence are used to
annotate the reconstructed volume. Then we exploit the scene structure in object class labelling by
performing inference over the meshed representation of the scene. By performing labelling over the
mesh we solve two issues: Firstly, images often have redundant information with multiple images
describing the same scene. Solving these images separately is slow, where our method is approximately
a magnitude faster in the inference stage compared to normal inference in the image domain.
Secondly, often multiple images, even though they describe the same scene result in inconsistent
labelling. By solving a single mesh, we remove the inconsistency of labelling across the images.
Also our mesh based labelling takes into account of the object layout in the scene, which is often
ambiguous in the image domain, thereby increasing the accuracy of object labelling. Finally, we perform
labelling and structure computation through a hierarchical robust PN Markov Random Field
defined on voxels and super-voxels given by an octree. This allows us to infer the 3D structure and
the object-class labels in a principled manner, through bounded approximate minimisation of a well
defined and studied energy functional. In this thesis, we also introduce two object labelled datasets
created from real world data. The 15 kilometre Yotta Labelled dataset consists of 8,000 images per
camera view of the roadways of the United Kingdom with a subset of them annotated with object
class labels and the second dataset is comprised of ground truth object labels for the publicly available
KITTI dataset. Both the datasets are available publicly and we hope will be helpful to the vision
research community
Robust Dense Mapping for Large-Scale Dynamic Environments
We present a stereo-based dense mapping algorithm for large-scale dynamic
urban environments. In contrast to other existing methods, we simultaneously
reconstruct the static background, the moving objects, and the potentially
moving but currently stationary objects separately, which is desirable for
high-level mobile robotic tasks such as path planning in crowded environments.
We use both instance-aware semantic segmentation and sparse scene flow to
classify objects as either background, moving, or potentially moving, thereby
ensuring that the system is able to model objects with the potential to
transition from static to dynamic, such as parked cars. Given camera poses
estimated from visual odometry, both the background and the (potentially)
moving objects are reconstructed separately by fusing the depth maps computed
from the stereo input. In addition to visual odometry, sparse scene flow is
also used to estimate the 3D motions of the detected moving objects, in order
to reconstruct them accurately. A map pruning technique is further developed to
improve reconstruction accuracy and reduce memory consumption, leading to
increased scalability. We evaluate our system thoroughly on the well-known
KITTI dataset. Our system is capable of running on a PC at approximately 2.5Hz,
with the primary bottleneck being the instance-aware semantic segmentation,
which is a limitation we hope to address in future work. The source code is
available from the project website (http://andreibarsan.github.io/dynslam).Comment: Presented at IEEE International Conference on Robotics and Automation
(ICRA), 201
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