Abstract
In this paper, we investigate the potential of vision-based object detection algorithms in underwater environments using several datasets to highlight the issues arising in different scenarios. Underwater computer vision has to cope with distortion and attenuation due to light propagation in water, and with challenging operating conditions. Scene segmentation and shape recognition in a single image must be carefully designed to achieve robust object detection and to facilitate object pose estimation. We describe a novel multi-feature object detection algorithm conceived to find human-made artefacts lying on the seabed. The proposed method searches for a target object according to a few general criteria that are robust to the underwater context, such as salient colour uniformity and sharp contours. We assess the performance of the proposed algorithm across different underwater datasets. The datasets have been obtained using stereo cameras of different quality, and diverge for the target object type and colour, acquisition depth and conditions. The effectiveness of the proposed approach has been experimentally demonstrated. Finally, object detection is discussed in connection with the simple colour-based segmentation and with the difficulty of tri-dimensional processing on noisy data.
Highlights
In recent years, the interest of the scientific community in underwater computer vision has increased, taking advant‐ age of the evolution of sensor technology and image processing algorithms
This paper has investigated vision-based object detection algorithms in underwater environments using multiple
This paper has investigated vision-based object detection algorithms in underwater environments using multiple datasets
Summary
The interest of the scientific community in underwater computer vision has increased, taking advant‐ age of the evolution of sensor technology and image processing algorithms. We investigate the potential of vision-based object detection algorithms in underwater environments using different datasets, including their contribution to underwater stereo vision processing. The differences among the datasets concern the camera quality, the experimental conditions (depth, light conditions, background, sensor guidance, etc.) and the target objects. Despite these differ‐ ences, the proposed algorithm achieves precise and reliable detection, while elementary colour-based segmentation approaches cannot reliably find a region of interest (ROI). In underwater environ‐ ments, stereo processing is usually not able to provide a reliable 3D representation of the scene enabling object recognition from shapes.
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