Abstract
Recently, deep learning (DL)-based hyperspectral image classification (HSIC) has attracted substantial attention. Many works based on the convolutional neural network (CNN) model have been certificated to be significantly successful for boosting the performance of HSIC. However, most of these methods extract features by using a fixed convolutional kernel and ignore multiscale features of the ground objects of hyperspectral images (HSIs). Although some recent methods have proposed multiscale feature extraction schemes, more computing and storage resources were consumed. Moreover, when using CNN to implement HSI classification, many methods only use the high-level semantic information extracted from the end of the network, ignoring the edge information extracted from shallow layers of the network. To settle the preceding two issues, a novel HSIC method based on hierarchical shrinkage multiscale network and the hierarchical feature fusion is proposed, with which the newly proposed classification framework can fuse features generated by both of multiscale receptive field and multiple levels. Specifically, multidepth and multiscale residual block (MDMSRB) is constructed by superposition dilated convolution to realize multiscale feature extraction. Furthermore, according to the change of feature size in different stages of the neural networks, we design a hierarchical shrinkage multiscale feature extraction network by pruning MDMSRB to reduce the redundancy of network structure. In addition, to make full use of the features extracted in each stage of the network, the proposed network hierarchically integrates low-level edge features and high-level semantic features effectively. Experimental results demonstrate that the proposed method achieves more competitive performance with a limited computational cost than other state-of-the-art methods.
Highlights
W ITH the rapid development of imaging spectrometers and platforms, imaging spectroscopy has gradually occupied a significant and Manuscript received March 17, 2021; revised April 15, 2021 and May 6, 2021; accepted May 20, 2021
In order to demonstrate the effectiveness of the proposed hierarchical shrinkage multiscale network (HSMSN)-hierarchical feature fusion (HFF) in hyperspectral image classification (HSIC), three real benchmark hyperspectral images (HSIs) datasets are used in experiments: Indian Pines (IP), University of Pavia (PU), and Salinas (SA)
2) Effect of Spatial Size on Classification Performance: For the convolutional neural network (CNN) adopted on HSIC, the input spatial size determines how much information the neural network can obtain from hyperspectral label samples neighborhood, which has a great impact on the classification results
Summary
W ITH the rapid development of imaging spectrometers and platforms, imaging spectroscopy ( called hyperspectral imaging) has gradually occupied a significant and Manuscript received March 17, 2021; revised April 15, 2021 and May 6, 2021; accepted May 20, 2021. The 3-D-CNN model achieved good classification performance, 3-D convolution operations will greatly increase the computational complexity and consume a lot of computing resources For this reason, 3-D and 2-D hierarchical extraction strategies of spectral-spatial features were proposed [35]–[37]. [48] and [49] can get good classification results, the multibranches structure inevitably makes the model larger and has a vast number of learnable parameters, which significantly increases the computing and storage burden These CNN-based methods have proved their powerful capacity for feature extraction, there are still some drawbacks that need to be overcome.
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
