Abstract
An important challenge in hyperspectral imaging tasks is to cope with the large number of spectral bins. Common spectral data reduction methods do not take prior knowledge about the task into account. Consequently, sparsely occurring features that may be essential for the imaging task may not be preserved in the data reduction step. Convolutional neural network (CNN) approaches are capable of learning the specific features relevant to the particular imaging task, but applying them directly to the spectral input data is constrained by the computational efficiency. We propose a novel supervised deep learning approach for combining data reduction and image analysis in an end-to-end architecture. In our approach, the neural network component that performs the reduction is trained such that image features most relevant for the task are preserved in the reduction step. Results for two convolutional neural network architectures and two types of generated datasets show that the proposed Data Reduction CNN (DRCNN) approach can produce more accurate results than existing popular data reduction methods, and can be used in a wide range of problem settings. The integration of knowledge about the task allows for more image compression and higher accuracies compared to standard data reduction methods.
Highlights
In hyperspectral imaging, data are collected for a large number of spectral bins from a wavelength range in the electromagnetic spectrum
The proposed data reduction approach is designed to be compatible with any existing Convolutional neural network (CNN)
We have proposed a task-driven end-to-end approach for supervised deep learning in hyperspectral imaging problems by adding a data reduction component to a convolutional neural network
Summary
Data are collected for a large number of spectral bins from a wavelength range in the electromagnetic spectrum. It is used in various fields [1], including agriculture classification [2,3], medical imaging [2,4,5], luggage and cargo inspection [2,6,7] and food quality assessment [8], as well as with energy-dispersive X-ray spectroscopy (EDX) and electron energy loss spectroscopy (EELS) [9]. In addition to the spatial dimensions, hyperspectral data include the spectral dimension which is typically large [10], often in the order of 102 to 103 spectral bins [11].
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