基于深度神经网络的不同天气条件下船舶鲁棒检测

Xin Nie, Meifang Yang, R. W. Liu
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引用次数: 25

摘要

基于深度学习的目标检测最近受到了学者和实践者的极大关注。然而,在恶劣的天气条件下,获取的图像往往会出现视觉质量下降,这可能会对实际应用中的目标检测产生负面影响。以往的研究大多基于图像恢复技术(如图像去雾、弱光图像增强等)可以在提高检测精度的同时改善视觉质量的假设来实现目标检测。相反,我们假设图像恢复技术(即图像预处理)也可能降低图像的精细细节,导致无法提高目标检测性能。在这项工作中,我们根据恶劣天气条件下的物理成像过程,直接提出了综合生成带有训练标签的退化图像,以扩大原始训练数据集,而原始训练数据集通常只包含正常天气条件下清晰的自然图像。然后在扩大的数据集上训练和测试了先进的YOLOv3模型,该数据集包含在不同天气条件下生成的合成和真实船舶图像。通过实验,将该方法与仅使用清晰图像的训练模型和使用(或不使用)图像预处理的测试模型进行了比较。结果表明,该模型在不同条件下均能取得较好的检测性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep Neural Network-Based Robust Ship Detection Under Different Weather Conditions
Deep learning-based object detection has recently received significant attention among scholars and practitioners. However, the acquired images often suffer from visual quality degradation under severe weather conditions, which could lead to negative effects on object detection in practical applications. Most previous studies proposed to implement object detection based on the assumption that image restoration techniques (e.g., image dehazing and low-light image enhancement, etc.) could improve visual quality while boosting detection accuracy. In contrast, we assumed that the image restoration techniques (i.e., image preprocessing) may also degrade the fine image details resulting in failing to promote object detection performance. In this work, according to the physical imaging process under severe weather conditions, we directly proposed to synthetically generate the degraded images with training labels to enlarge the original training datasets, which commonly contain only clear natural images under normal weather conditions. The advanced YOLOv3 model was then trained and tested on the enlarged dataset which contain both synthetic and realistic ship images generated under different weather conditions. Experiments have been conducted to compare the proposed method with other competing methods which implement training model only with clear images and testing model with (or without) image preprocessing. Results illustrated that our model could achieve superior detection performance under different conditions.
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