4 research outputs found
Classification of Polarimetric SAR Images Using Compact Convolutional Neural Networks
Classification of polarimetric synthetic aperture radar (PolSAR) images is an
active research area with a major role in environmental applications. The
traditional Machine Learning (ML) methods proposed in this domain generally
focus on utilizing highly discriminative features to improve the classification
performance, but this task is complicated by the well-known "curse of
dimensionality" phenomena. Other approaches based on deep Convolutional Neural
Networks (CNNs) have certain limitations and drawbacks, such as high
computational complexity, an unfeasibly large training set with ground-truth
labels, and special hardware requirements. In this work, to address the
limitations of traditional ML and deep CNN based methods, a novel and
systematic classification framework is proposed for the classification of
PolSAR images, based on a compact and adaptive implementation of CNNs using a
sliding-window classification approach. The proposed approach has three
advantages. First, there is no requirement for an extensive feature extraction
process. Second, it is computationally efficient due to utilized compact
configurations. In particular, the proposed compact and adaptive CNN model is
designed to achieve the maximum classification accuracy with minimum training
and computational complexity. This is of considerable importance considering
the high costs involved in labelling in PolSAR classification. Finally, the
proposed approach can perform classification using smaller window sizes than
deep CNNs. Experimental evaluations have been performed over the most
commonly-used four benchmark PolSAR images: AIRSAR L-Band and RADARSAT-2 C-Band
data of San Francisco Bay and Flevoland areas. Accordingly, the best obtained
overall accuracies range between 92.33 - 99.39% for these benchmark study
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Machine Learning in Sensors and Imaging
Machine learning is extending its applications in various fields, such as image processing, the Internet of Things, user interface, big data, manufacturing, management, etc. As data are required to build machine learning networks, sensors are one of the most important technologies. In addition, machine learning networks can contribute to the improvement in sensor performance and the creation of new sensor applications. This Special Issue addresses all types of machine learning applications related to sensors and imaging. It covers computer vision-based control, activity recognition, fuzzy label classification, failure classification, motor temperature estimation, the camera calibration of intelligent vehicles, error detection, color prior model, compressive sensing, wildfire risk assessment, shelf auditing, forest-growing stem volume estimation, road management, image denoising, and touchscreens
Classification of PolSAR Images Using Multilayer Autoencoders and a Self-Paced Learning Approach
In this paper, a novel polarimetric synthetic aperture radar (PolSAR) image classification method based on multilayer autoencoders and self-paced learning (SPL) is proposed. The multilayer autoencoders network is used to learn the features, which convert raw data into more abstract expressions. Then, softmax regression is applied to produce the predicted probability distributions over all the classes of each pixel. When we optimize the multilayer autoencoders network, self-paced learning is used to accelerate the learning convergence and achieve a stronger generalization capability. Under this learning paradigm, the network learns the easier samples first and gradually involves more difficult samples in the training process. The proposed method achieves the overall classification accuracies of 94.73%, 94.82% and 78.12% on the Flevoland dataset from AIRSAR, Flevoland dataset from RADARSAT-2 and Yellow River delta dataset, respectively. Such results are comparable with other state-of-the-art methods