Abstract
The interpretation of land use and land cover (LULC) is an important issue in the fields of high-resolution remote sensing (RS) image processing and land resource management. Fully training a new or existing convolutional neural network (CNN) architecture for LULC classification requires a large amount of remote sensing images. Thus, fine-tuning a pre-trained CNN for LULC detection is required. To improve the classification accuracy for high resolution remote sensing images, it is necessary to use another feature descriptor and to adopt a classifier for post-processing. A fully connected conditional random fields (FC-CRF), to use the fine-tuned CNN layers, spectral features, and fully connected pairwise potentials, is proposed for image classification of high-resolution remote sensing images. First, an existing CNN model is adopted, and the parameters of CNN are fine-tuned by training datasets. Then, the probabilities of image pixels belong to each class type are calculated. Second, we consider the spectral features and digital surface model (DSM) and combined with a support vector machine (SVM) classifier, the probabilities belong to each LULC class type are determined. Combined with the probabilities achieved by the fine-tuned CNN, new feature descriptors are built. Finally, FC-CRF are introduced to produce the classification results, whereas the unary potentials are achieved by the new feature descriptors and SVM classifier, and the pairwise potentials are achieved by the three-band RS imagery and DSM. Experimental results show that the proposed classification scheme achieves good performance when the total accuracy is about 85%.
Highlights
Remote sensing has become an important means of obtaining information about the earth’s surface
We develop a novel approach for high-resolution remote sensing imagery per-pixel classification of four classes using fine-tuned convolutional neural networks (CNN), spectral features, and fully connected conditional random fields (FC-conditional random fields (CRF)), which are effective for land use and land cover (LULC) classification, achieving a classification accuracy of 85%
In CMP-support vector machine (SVM), the concatenating feature of fine-tuned CNN probabilities and SD-SVM probabilities are considered as the feature descriptors, and SVM classifier is used for LULC classification
Summary
Remote sensing has become an important means of obtaining information about the earth’s surface. With the continuous improvements in sensor technology, high-resolution multi-spectral images can be obtained, such as IKONOS, QuickBird, WorldView-2, ZY-3C, and GF-1, as well as high-resolution remote sensing data with spatial resolution close to one meter or even the sub-meter level. With Unmanned Aerial Vehicle (UAV) aerial technology, a large number of decimeter-scale ultra-high resolution remote sensing images can be acquired. The interpretation of high-resolution remote sensing images, especially high spatial resolution images, is of paramount importance in many practical areas, such as urban environments, precision agriculture, infrastructure, forestry survey, military target identification, and disaster assessment. Image classification is an important step in many remote sensing applications and refers to the task of identifying the category of every pixel in an image. Three main CNN strategies have been successfully adopted for remote sensing image classification: (1) full trained CNN, (2) fine-tuned CNN, and (3) pre-trained CNN used as feature extractors [1,2]
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
