Thermal remote sensing
Thermal remote sensing is a branch of
Principles
Thermal remote sensing is working on two major laws which are as follows:[2]
1. Stefan–Boltzmann law: Surface temperature of any objects radiate energy and shows specific properties. These properties are calculated by Boltzmann law.
2. Wien's displacement law: Wien's displacement law explains the relation between temperature and the wavelength of radiation. It states that the wavelength of radiation emitted from a blackbody is inversely proportional to the temperature of the black body.
Applications
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Thermal remote sensing is used in applications including:
- Identification of geological units and structures[1]
- Soil moisture studies[5]
- Forest fires: Thermal remote sensing plays a vital role in the determination of Forest fire based on the principle of identifying fire pixel according to the temperature difference between the energy emitting from the surface and ambient temperature.[2]
- Coal fires[9]
- Intelligence / military applications[13]
- Heat loss from buildings[14]
Land Surface Temperature (LST)
One of the most important applications of thermal remote sensing in earth sciences is to calculate the Land Surface Temperature (LST). LST is a measurement of how hot the land is to the touch. It differs from air temperature (the temperature given in weather reports) because land heats and cools more quickly than air.[15] LST is a key variable that is required to accurately model the surface energy budge.[16] Thermal remote sensing from satellites to derive land surface temperatures has a long history that can be traced back to the TIROS-II satellite, launched in the early 60s.[17] From the outset certain problems were recognised when deriving temperatures over the land, most notably the low temperatures observed over deserts. To quantify the effects of the atmosphere and the surface (emissivity effects) and, both from theory and experiment, various algorithms developed to derive LST.[16] These algorithms are different in terms of accuracy and application.
Satellites thermal bands
The
Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) utilizes a unique combination of wide spectral coverage and high spatial resolution in the visible near-infrared through shortwave infrared to the thermal infrared regions. The ASTER instruments acquire thermal data in Thermal Infrared (TIR) 90 meter Bands (bands 10-14).
The
Given recent developments in UAVs, thermal images with high spatial and temporal resolutions have become available at a low cost.
References
- ^ a b Prakash, Anupma (2000). "Thermal remote sensing: concepts, issues and applications" (PDF). International Archives of Photogrammetry and Remote Sensing. 33(B1, PART 1): 239–243.
- ^ ISBN 978-0-323-99262-6, retrieved 2023-12-10
- ISSN 1569-8432.
- S2CID 257680037.
- ISSN 1673-7490.
- ISSN 0309-1708.
- ISSN 2072-4292.
- ISSN 2214-241X.
- S2CID 140197767.
- ISSN 1474-7065.
- ISSN 0924-2716.
- ISSN 0168-1923.
- PMID 27548174.
- PMID 34677303.
- ^ "Vegetation & Land Surface Temperature". earthobservatory.nasa.gov. 2023-07-31. Retrieved 2023-12-11.
- ^ ISSN 0275-7257.
- ISSN 0022-4928.
- ^ "What are the band designations for the Landsat satellites? | U.S. Geological Survey". www.usgs.gov. Retrieved 2023-12-10.
- ^ "USGS EROS Archive - Advanced Very High Resolution Radiometer (AVHRR) - Sensor Characteristics | U.S. Geological Survey". www.usgs.gov. Retrieved 2023-12-11.