Abstract
Unmanned aerial vehicles (UAV) are being used for low altitude remote sensing for thematic land classification using visible light and multi-spectral sensors. The objective of this work was to investigate the use of UAV equipped with a compact spectrometer for land cover classification. The UAV platform used was a DJI Flamewheel F550 hexacopter equipped with GPS and Inertial Measurement Unit (IMU) navigation sensors, and a Raspberry Pi processor and camera module. The spectrometer used was the FLAME-NIR, a near-infrared spectrometer for hyperspectral measurements. RGB images and spectrometer data were captured simultaneously. As spectrometer data do not provide continuous terrain coverage, the locations of their ground elliptical footprints were determined from the bundle adjustment solution of the captured images. For each of the spectrometer ground ellipses, the land cover signature at the footprint location was determined to enable the characterization, identification, and classification of land cover elements. To attain a continuous land cover classification map, spatial interpolation was carried out from the irregularly distributed labeled spectrometer points. The accuracy of the classification was assessed using spatial intersection with the object-based image classification performed using the RGB images. Results show that in homogeneous land cover, like water, the accuracy of classification is 78% and in mixed classes, like grass, trees and manmade features, the average accuracy is 50%, thus, indicating the contribution of hyperspectral measurements of low altitude UAV-borne spectrometers to improve land cover classification.
Highlights
Introduction and ObjectivesIn recent times, small Unmanned aerial vehicles (UAV) platforms have been extensively used for low altitude remote sensing and thematic land cover classification, which is one of the main purposes of remote sensing
In this study, we present an approach to obtain land cover classification using a FLAME-near infrared (NIR) spectrometer which has a preconfigured range from 950 to 1650 nm and a Raspberry pi camera mounted on the UAV
The generated object-based image segmentation was used as reference land cover to assess the accuracy of the classification map produced by the interpolation of labeled spectrometer points
Summary
Small UAV platforms have been extensively used for low altitude remote sensing and thematic land cover classification, which is one of the main purposes of remote sensing. Light weight multispectral, hyperspectral and thermal imaging sensors are used. A spectrometer measures the spectral signatures of all ground features within the sensor's field of view by analyzing the spectral characteristics of light radiation and breaking down the incoming energy into different wavelengths. Because of the light weight and reliable performance of the spectrometers, they are mounted on a UAV and used to capture data in several bands. Multispectral and hyperspectral cameras capture several bands of the electromagnetic spectrum and provide continuous gridded pixel area coverage, the spectrometer’s coverage consists of single pixel footprints determined by its field of view; its high spectral resolution makes it a good alternative to multispectral sensors. We present a land cover classification method
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