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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia
Conclusion
Climate change has a significant impact on glaciers,
which are very sensitive to changes in atmospheric
conditions. Long term temperature observations over
the glaciated terrains of the Himalaya can therefore
provide a detailed understanding of climate change in
the region. The main aim of this investigation was to
examine a methodology for the estimation of Land
surface temperatures from satellite data. The resulting
estimated land surface temperatures were compared
to NCEP modeled Surface temperature and the
results showed a good correlation. The derived Land
surface temperatures were compared with daily
average mean surface temperatures modeled by the
NCEP. The NCEP modeled temperature was found to
be cooler than the extracted surface temperature,
which is a realistic expectation. The results show that
the satellite derived temperatures values are in the
acceptable range. The present results show that
satellite data can provide regionally representative
values for surface temperatures, which is not possible
from ground observations given the scarcity of data.
The derived surface temperature values are found to
be in good agreement with the field measured values,
indicating that the methodology can be adopted for
the Investigation over Himalayan region.
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