Abstract
Despite recent advances in image and video processing, the detection of people or cars in areas of dense vegetation is still challenging due to landscape, illumination changes and strong occlusion. In this paper, we address this problem with the use of a hyperspectral camera—installed on the ground or possibly a drone—and detection based on spectral signatures. We introduce a novel automatic method for annotating spectral signatures based on a combination of state-of-the-art deep learning methods. After we collected millions of samples with our method, we used a deep learning approach to train a classifier to detect people and cars. Our results show that, based only on spectral signature classification, we can achieve an Matthews Correlation Coefficient of 0.83. We evaluate our classification method in areas with varying vegetation and discuss the limitations and constraints that the current hyperspectral imaging technology has. We conclude that spectral signature classification is possible with high accuracy in uncontrolled outdoor environments. Nevertheless, even with state-of-the-art compact passive hyperspectral imaging technology, high dynamic range of illumination and relatively low image resolution continue to pose major challenges when developing object detection algorithms for areas of dense vegetation.
Highlights
Multispectral and hyperspectral imaging allows more detailed observation of the spectral signature of materials as compared to conventional RGB cameras
We address this problem with the use of a hyperspectral camera—installed on the ground or possibly a drone—and detection based on spectral signatures
We introduce a novel automatic method for annotating spectral signatures based on a combination of state-of-the-art deep learning methods
Summary
Multispectral and hyperspectral imaging allows more detailed observation of the spectral signature of materials as compared to conventional RGB cameras. Similar to adding color information to a grayscale image that requires recording the intensity in three different wavelength bands, a hyperspectral camera is able to capture information on the radiance of recorded materials in many, potentially non-visible, bands. This technology is widely used for satellite and airborne recordings, where the most common use cases are related to agriculture [1,2,3], vegetation monitoring [4,5,6] and mineralogy [7]. Puttonen et al [13] used an active hyperspectral LiDAR and showed 92.3% accuracy for detecting camouflage versus vegetation
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