Abstract
Aircraft detection from high-resolution remote sensing images is important for civil and military applications. Recently, detection methods based on deep learning have rapidly advanced. However, they require numerous samples to train the detection model and cannot be directly used to efficiently handle large-area remote sensing images. A weakly supervised learning method (WSLM) can detect a target with few samples. However, it cannot extract an adequate number of features, and the detection accuracy requires improvement. We propose a cascade convolutional neural network (CCNN) framework based on transfer-learning and geometric feature constraints (GFC) for aircraft detection. It achieves high accuracy and efficient detection with relatively few samples. A high-accuracy detection model is first obtained using transfer-learning to fine-tune pretrained models with few samples. Then, a GFC region proposal filtering method improves detection efficiency. The CCNN framework completes the aircraft detection for large-area remote sensing images. The framework first-level network is an image classifier, which filters the entire image, excluding most areas with no aircraft. The second-level network is an object detector, which rapidly detects aircraft from the first-level network output. Compared with WSLM, detection accuracy increased by 3.66%, false detection decreased by 64%, and missed detection decreased by 23.1%.
Highlights
Aircraft detection from remote sensing images is a type of small target recognition under a wide range
The network models used in the experiments were VGG16 pretrained with ImageNet
Using the transfer-learning method, the parameters of the existing target detection model were fine-tuned with a small number of samples, and a high-accuracy aircraft detection model was obtained
Summary
Aircraft detection from remote sensing images is a type of small target recognition under a wide range. It has two problems, one is the efficiency of large-area image detection; the other is the aircraft feature extraction and expression in complex environments. Adjustment and optimization of the algorithm can improve the detection accuracy and efficiency [6] These features are common image attributes; it is difficult to fundamentally distinguish between the target and background. The multifeature fusion method is often used to comprehensively describe the target [9] It increases the algorithm complexity and reduces the detection efficiency to some extent [7, 10]
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