712 research outputs found
Fast, Accurate Thin-Structure Obstacle Detection for Autonomous Mobile Robots
Safety is paramount for mobile robotic platforms such as self-driving cars
and unmanned aerial vehicles. This work is devoted to a task that is
indispensable for safety yet was largely overlooked in the past -- detecting
obstacles that are of very thin structures, such as wires, cables and tree
branches. This is a challenging problem, as thin objects can be problematic for
active sensors such as lidar and sonar and even for stereo cameras. In this
work, we propose to use video sequences for thin obstacle detection. We
represent obstacles with edges in the video frames, and reconstruct them in 3D
using efficient edge-based visual odometry techniques. We provide both a
monocular camera solution and a stereo camera solution. The former incorporates
Inertial Measurement Unit (IMU) data to solve scale ambiguity, while the latter
enjoys a novel, purely vision-based solution. Experiments demonstrated that the
proposed methods are fast and able to detect thin obstacles robustly and
accurately under various conditions.Comment: Appeared at IEEE CVPR 2017 Workshop on Embedded Visio
6D Visual Odometry with Dense Probabilistic Egomotion Estimation
Proceedings of the International Conference on Computer Vision Theory and Applications, 361-365, 2013, Barcelona, SpainWe present a novel approach to 6D visual odometry for vehicles with calibrated stereo cameras. A dense probabilistic egomotion (5D) method is combined with robust stereo feature based approaches and Extended Kalman Filtering (EKF) techniques to provide high quality estimates of vehicle’s angular and linear velocities. Experimental results show that the proposed method compares favorably with state-the-art approaches, mainly in the estimation of the angular velocities, where significant improvements are achieved
Exploring Convolutional Networks for End-to-End Visual Servoing
Present image based visual servoing approaches rely on extracting hand
crafted visual features from an image. Choosing the right set of features is
important as it directly affects the performance of any approach. Motivated by
recent breakthroughs in performance of data driven methods on recognition and
localization tasks, we aim to learn visual feature representations suitable for
servoing tasks in unstructured and unknown environments. In this paper, we
present an end-to-end learning based approach for visual servoing in diverse
scenes where the knowledge of camera parameters and scene geometry is not
available a priori. This is achieved by training a convolutional neural network
over color images with synchronised camera poses. Through experiments performed
in simulation and on a quadrotor, we demonstrate the efficacy and robustness of
our approach for a wide range of camera poses in both indoor as well as outdoor
environments.Comment: IEEE ICRA 201
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