Abstract
Remote-sensing image scene classification can provide significant value, ranging from forest fire monitoring to land-use and land-cover classification. Beginning with the first aerial photographs of the early 20th century to the satellite imagery of today, the amount of remote-sensing data has increased geometrically with a higher resolution. The need to analyze these modern digital data motivated research to accelerate remote-sensing image classification. Fortunately, great advances have been made by the computer vision community to classify natural images or photographs taken with an ordinary camera. Natural image datasets can range up to millions of samples and are, therefore, amenable to deep-learning techniques. Many fields of science, remote sensing included, were able to exploit the success of natural image classification by convolutional neural network models using a technique commonly called transfer learning. We provide a systematic review of transfer learning application for scene classification using different datasets and different deep-learning models. We evaluate how the specialization of convolutional neural network models affects the transfer learning process by splitting original models in different points. As expected, we find the choice of hyperparameters used to train the model has a significant influence on the final performance of the models. Curiously, we find transfer learning from models trained on larger, more generic natural images datasets outperformed transfer learning from models trained directly on smaller remotely sensed datasets. Nonetheless, results show that transfer learning provides a powerful tool for remote-sensing scene classification.
Highlights
Over the past decades, remote sensing has experienced dramatic changes in data quality, spatial resolution, shorter revisit times, and available area covered
It seems that the step size (2e-3) is too large for fine tuning in the VGG19 model, such that the VGG19 intermediate and deep models trained on fine tune and randomly initialized weights modes fall in local minima
Our objective with this paper was to investigate the use of transfer learning in the analysis of remote-sensing data, as well as how the convolutional neural network (CNN) performance depends on the depth of the network and on the amount of training data available
Summary
Remote sensing has experienced dramatic changes in data quality, spatial resolution, shorter revisit times, and available area covered. Emery and Camps [1] reported that our ability to observe the Earth from low Earth orbit and geostationary satellites has been improving continuously Such an increase requires a significant change in the way we use and manage remote-sensing images. Scene classification is a fundamental remote-sensing task and important for many practical remote-sensing applications, such as urban planning [4], land management [5], and to characterize wild fires [6,7], among other applications.
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