Abstract
Hyperspectral image (HSI) consists of hundreds of narrow spectral band components with rich spectral and spatial information. Extreme Learning Machine (ELM) has been widely used for HSI analysis. However, the classical ELM is difficult to use for sparse feature leaning due to its randomly generated hidden layer. In this paper, we propose a novel unsupervised sparse feature learning approach, called Evolutionary Multiobjective-based ELM (EMO-ELM), and apply it to HSI feature extraction. Specifically, we represent the task of constructing the ELM Autoencoder (ELM-AE) as a multiobjective optimization problem that takes the sparsity of hidden layer outputs and the reconstruction error as two conflicting objectives. Then, we adopt an Evolutionary Multiobjective Optimization (EMO) method to solve the two objectives, simultaneously. To find the best solution from the Pareto solution set and construct the best trade-off feature extractor, a curvature-based method is proposed to focus on the knee area of the Pareto solutions. Benefited from the EMO, the proposed EMO-ELM is less prone to fall into a local minimum and has fewer trainable parameters than gradient-based AEs. Experiments on two real HSIs demonstrate that the features learned by EMO-ELM not only preserve better sparsity but also achieve superior separability than many existing feature learning methods.
Highlights
Hyperspectral Imagery (HSI), which is obtained by remote sensing systems, contains high-resolution spectral information over a wide range of the electromagnetic spectrum with hundreds of observed spectral bands [1]
This paper proposed an Evolutionary Multiobjective Optimization (EMO)-Extreme Learning Machine (ELM) approach for sparse feature learning of hyperspectral image
The main idea of Evolutionary Multiobjective-based ELM (EMO-ELM) is that, firstly, using an EMO to optimize the hidden layer of ELM, executing feature extraction according to the optimal hidden layer
Summary
Hyperspectral Imagery (HSI), which is obtained by remote sensing systems, contains high-resolution spectral information over a wide range of the electromagnetic spectrum with hundreds of observed spectral bands [1]. HSI has been applied in a wide variety of applications, including agriculture, surveillance, astronomy, and biomedical imaging, among others [3]. A great number of redundancies between spectral bands bring heavy computation burdens in HSI data analysis [4]. Feature learning overcomes these issues and guarantees good classification accuracy [7,8,9,10,11,12,13]. The conventional feature learning methods, such as Principal Component Analysis (PCA) [9] and its variants [14,15,16] are widely applied in HSI.
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