Abstract
Hyperspectral image (HSI) classification aims at assigning each pixel a pre-defined class label, which underpins lots of vision related applications, such as remote sensing, mineral exploration and ground object identification, etc. Lots of classification methods thus have been proposed for better hyperspectral imagery interpretation. Witnessing the success of convolutional neural networks (CNNs) in the traditional images based classification tasks, plenty of efforts have been made to leverage CNNs to improve HSI classification. An advanced CNNs architecture uses the kernels generated from the clustering method, such as a K-means network uses K-means to generate the kernels. However, the above methods are often obtained heuristically (e.g., the number of kernels should be assigned manually), and how to data-adaptively determine the number of convolutional kernels (i.e., filters), and thus generate the kernels that better represent the data, are seldom studied in existing CNNs based HSI classification methods. In this study, we propose a new CNNs based HSI classification method where the convolutional kernels can be automatically learned from the data through clustering without knowing the cluster number. With those data-adaptive kernels, the proposed CNNs method achieves better classification results. Experimental results from the datasets demonstrate the effectiveness of the proposed method.
Highlights
Different from traditional images (e.g., RGB image), hyperspectral image (HSI) contains a continuous spectrum at each pixel, which is beneficial for identifying different imaged land covers.With such abundant spectral information, hyperspectral image (HSI) classification that aims at assigning each pixel a pre-defined class label has facilitated various applications, such as mineral exploration, ground object identification, survey of agriculture and monitoring of geology, etc.plenty of efforts have been made in HSI classification
We propose a novel convolutional neural networks (CNNs) classification framework for HSIs, which can data-adaptively learn a specific number of kernels from the training data
This model adopts the MCFSFDP algorithm to cluster the training data, and the convolutional kernels can be determined automatically by the cluster center and inter-cluster margin. With those pre-learned kernels, a CNNs framework is developed for classifications
Summary
Different from traditional images (e.g., RGB image), hyperspectral image (HSI) contains a continuous spectrum at each pixel, which is beneficial for identifying different imaged land covers.With such abundant spectral information, hyperspectral image (HSI) classification that aims at assigning each pixel a pre-defined class label has facilitated various applications, such as mineral exploration, ground object identification, survey of agriculture and monitoring of geology, etc.plenty of efforts have been made in HSI classification. Different from traditional images (e.g., RGB image), hyperspectral image (HSI) contains a continuous spectrum at each pixel, which is beneficial for identifying different imaged land covers. With such abundant spectral information, hyperspectral image (HSI) classification that aims at assigning each pixel a pre-defined class label has facilitated various applications, such as mineral exploration, ground object identification, survey of agriculture and monitoring of geology, etc. For hand-crafted feature based methods, HSI is often represented by the features designed manually [1,2,3,4,5,6,7] Due to their shallow structure, the representation ability of such features is limited, especially for HSIs which often exhibit high nonlinearity aroused by the high-dimensionality and mixture of pixels
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