Abstract
Remote Sensing plays very important role in many different study fields, like hydrology, crop management, environmental and ecosystem studies. For all mentioned areas of interest different remote sensing and image processing techniques, such as: image classification (object and pixel- based), object identification, change detection, etc. can be applied. Most of this techniques use spectral reflectance coefficients as the basis for the identification and distinction of different objects and materials, e.g. monitoring of vegetation stress, identification of water pollutants, yield identification, etc. Spectral characteristics are usually acquired using discrete methods such as spectrometric measurements in both laboratory and field conditions. Such measurements however can be very time consuming, which has led many international researchers to investigate the reliability and accuracy of using image-based methods. According to published and ongoing studies, in order to acquire these spectral characteristics from images, it is necessary to have hyperspectral data. The presented article describes a series of experiments conducted using the push-broom Headwall MicroHyperspec A-series VNIR. This hyperspectral scanner allows for registration of images with more than 300 spectral channels with a 1.9 nm spectral bandwidth in the 380- 1000 nm range. The aim of these experiments was to establish a methodology for acquiring spectral reflectance characteristics of different forms of land cover using such sensor. All research work was conducted in controlled conditions from low altitudes. Hyperspectral images obtained with this specific type of sensor requires a unique approach in terms of post-processing, especially radiometric correction. Large amounts of acquired imagery data allowed the authors to establish a new post- processing approach. The developed methodology allowed the authors to obtain spectral reflectance coefficients from a hyperspectral sensor mounted on an unmanned aerial vehicle, ensuring a high accuracy of obtained data.
Highlights
Nowadays remote sensing allows to obtain a number of very detailed information about investigated objects
The main aim of this paper is to present applied methodology for determining the relationship between exposure parameters of the hyperspectral camera and light intensity in order to determine absolute spectral reflectance characteristics from the hyperspectral imagery without previous calibration of the imaging sensor
The main aim of this paper is to present briefly applied methodology for determining the relationship between exposure parameters of the hyperspectral camera and light intensity in order to determine absolute spectral reflectance characteristics from the hyperspectral imagery without previous calibration of the imaging sensor
Summary
Nowadays remote sensing allows to obtain a number of very detailed information about investigated objects. The foundation of modern remote sensing is spectroscopy, that is a science that allows for acquiring and analyses of electromagnetic spectra, which are results of interactions between electromagnetic radiation with objects. This science is used for all issues related to the description of matters’ structure and identification of substances and is an object of studies in the field of physic, astronomy, chemistry, genetic engineering, natural science and many. Because all particular particles absorb radiation in a characteristic way (depending on wavelength used and the chemical bonds making up the investigated substance), it is possible to identify objects and substances using just their spectral characteristics (Kirkbride, 2000)
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