Abstract
With the development of science and technology, neural networks, as an effective tool in image processing, play an important role in gradual remote-sensing image-processing. However, the training of neural networks requires a large sample database. Therefore, expanding datasets with limited samples has gradually become a research hotspot. The emergence of the generative adversarial network (GAN) provides new ideas for data expansion. Traditional GANs either require a large number of input data, or lack detail in the pictures generated. In this paper, we modify a shuffle attention network and introduce it into GAN to generate higher quality pictures with limited inputs. In addition, we improved the existing resize method and proposed an equal stretch resize method to solve the problem of image distortion caused by different input sizes. In the experiment, we also embed the newly proposed coordinate attention (CA) module into the backbone network as a control test. Qualitative indexes and six quantitative evaluation indexes were used to evaluate the experimental results, which show that, compared with other GANs used for picture generation, the modified Shuffle Attention GAN proposed in this paper can generate more refined and high-quality diversified aircraft pictures with more detailed features of the object under limited datasets.
Highlights
Remote Sensing (RS) refers to the non-contact remote detection technology
There is no obvious distortion in the fake image generated by the equal stretch resize method proposed this paper
The results of the existing image generation generative adversarial network (GAN) models and the network proposed in this paper are analyzed qualitatively and quantitatively, respectively
Summary
Remote Sensing (RS) refers to the non-contact remote detection technology. Images obtained by remote sensing technology cover a large range of landforms and features, which contain a lot of information. Remote-sensing image interpretation is used to judge the natural landform, artificial terrain, and target information of the RS images, which is widely used in civil fields such as ground feature coverage [1,2,3] and forest detection [4]. RS images often have a huge amount of information while the targets are difficult to observe, which brings a great challenge and heavy burden to traditional manual interpretation. The machine interpretation of RS images mainly consists of the detection and classification of terrain, landform, and target [8,9]. With the rapid development of neural networks in the field of natural image processing, the method of extracting the depth characteristics has been applied in the processing of RS images to maintain better performance
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