Real-time obstacle detection using range images: processing dynamically-sized sliding windows on a GPU

An efficient obstacle detection technique is required so that navigating robots can avoid obstacles and potential hazards. This task is usually simplified by relying on structural patterns. However, obstacle detection constitutes a challenging problem in unstructured unknown environments, where such...

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Bibliographic Details
Published in:Robotica 2017-01, Vol.35 (1), p.85-100
Main Authors: Mendes, Caio César Teodoro, Osório, Fernando Santos, Wolf, Denis Fernando
Format: Article
Language:English
Subjects:
Computation
Computational efficiency
Graphics processing units
Obstacle avoidance
Obstacles
Real time
Robots
Sliding
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Summary:An efficient obstacle detection technique is required so that navigating robots can avoid obstacles and potential hazards. This task is usually simplified by relying on structural patterns. However, obstacle detection constitutes a challenging problem in unstructured unknown environments, where such patterns may not exist. Talukder et al. (2002, IEEE Intelligent Vehicles Symposium, pp. 610–618.) successfully derived a method to deal with such environments. Nevertheless, the method has a high computational cost and researchers that employ it usually rely on approximations to achieve real-time. We hypothesize that by using a graphics processing unit (GPU), the computing time of the method can be significantly reduced. Throughout the implementation process, we developed a general framework for processing dynamically-sized sliding windows on a GPU. The framework can be applied to other problems that require similar computation. Experiments were performed with a stereo camera and an RGB-D sensor, where the GPU implementations were compared to multi-core and single-core CPU implementations. The results show a significant gain in the computational performance, i.e. in a particular instance, a GPU implementation is almost 90 times faster than a single-core one.
ISSN:0263-5747
1469-8668
DOI:10.1017/S0263574714002914