Abstract
Single-image super-resolution (SR) is an effective approach to enhance spatial resolution for numerous applications such as object detection and classification when the resolution of sensors is limited. Although deep convolutional neural networks (CNNs) proposed for this purpose in recent years have outperformed relatively shallow models, enormous parameters bring the risk of overfitting. In addition, due to the different scale of objects in images, the hierarchical features of deep CNN contain additional information for SR tasks, while most CNN models have not fully utilized these features. In this paper, we proposed a deep yet concise network to address these problems. Our network consists of two main structures: (1) recursive inference block based on dense connection reuse of local low-level features, and recursive learning is applied to control the model parameters while increasing the receptive fields; (2) a bidirectional convolutional LSTM (BiConvLSTM) layer is introduced to learn the correlations of features from each recursion and adaptively select the complementary information for the reconstruction layer. Experiments on multispectral satellite images, panchromatic satellite images, and nature high-resolution remote-sensing images showed that our proposed model outperformed state-of-the-art methods while utilizing fewer parameters, and ablation studies demonstrated the effectiveness of a BiConvLSTM layer for an image SR task.
Highlights
In the field of remote sensing, high-resolution (HR) images contain many detailed textures and critical information, which are essential for object classification and detection tasks
We describe the generation of the multispectral satellite image dataset and image dataset for training and testing our network
We undertook several experiments to understand the properties of our model, and the effect of increasing the number of recursions is investigated in Sections 3.2 and 3.3
Summary
In the field of remote sensing, high-resolution (HR) images contain many detailed textures and critical information, which are essential for object classification and detection tasks. In the multi-frame method, establishing the relation between a targeted HR image and several LR images of the same scene acquired at different condition is used to create a higher resolution result. Single-image SR algorithms have to solely rely on one given input image, which is crucial when there is no additional data available. Single-image SR methods can be efficiently used as pre-processing operations for additional manual or automatic processing steps, such as classification or object extraction in general. With the loss of high-frequency detailed information and multiple targets for a single LR image, the SR task is an ill-posed inverse problem
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
