JAPRS & SIS, Vol.34, Part 7, “Resource and Environmental Monitoring”, Hyderabad, India, 2002 
  
  
7.1 Methodology 
Keeping in view the facilities available with various 
organisations in the country, the methodology for the national 
mission should consists of visual interpretation of satellite data 
for various types of degraded lands, selection of sample points 
based on satistical criteria, ground truth, soil sample analysis 
and finalisation of maps with uniform legend. The methodology 
manual should be prepared that gives guide lines for carrying 
out the work. The working level personnel should be trained 
before taking up the project work. This enables to generate a 
uniform data base subsequently. Image interpretation key need 
to be developed based on image characteristics viz. tone, 
texture, pattern, size, shadow, shape, location and association. 
The interpretation of all the satellite imagery has to be carried 
out following standard procedure of image interpretation 
covering the steps i.e., recognition, identification, analysis and 
inferences. Multi-date remotely sensed data is planned to be 
used in the visual interpretation technique for better abstraction 
of different image element, vis-à-vis degraded lands. 
7.2 Legend Development 
Development of mapping legend is a state of art in land 
resource mapping to depict the various land information on 
map in a comprehensive manner. This calls for the 
development of Nation-wide land degradation mapping legend. 
Ministry of Agriculture has developed mapping legend for land 
degradation, which requires fine-tuning before adopting for the 
mission mode project. (DAC, 1994) 
CONCLUSION 
The concern for protecting the productivity of natural resources 
without further degradation is the key issue for both developed 
and developing nations to sustain the future generations. 
Reclamation / management of degraded land is one of the 
options available to increase area under cultivation and also to 
improve the productivity from such lands. 
Although the total geographical area affected or likely to be 
affected by various degradational/desertification processes is 
large and growing throughout the world, its total dimensions 
are not known with the necessary degree of accuracy and 
reliability. Accurate and reliable figures concerning the states, 
extent and rate of desertification for the country is needed for 
the development of land degradation information system, so 
that further monitoring at reasonable ume intervals would be 
more realistic for sustainable agricultural production for the 
posterity. 
There are positive examples of utilizing the satellite remote 
sensing technology for the assessment of status and rate of 
desertification but the methodology has to be further simplified. 
For the general uniform utilization in different countries. For 
this, it seems imperative to refine the definition of 
desertification or land degradation in order to make it more 
precise and operative. It should contain clear identification of 
measurable parameter (s) that can indicate the extent, degree 
and rate of the process(s). 
The satellite remote sensing and GIS technologies should be 
fully utilized for monitoring the land degradation/desertification 
processes at reasonable time intervals say once in 10 years 
giving sufficient time for undertaking reclamation/conservation 
measures in the degraded areas. Future space borne remote 
sensing sensors with higher spatial, spectral, radiometric and 
692 
temporal resolutions are expected to resolve some of the key 
issues not addressed by the current sensors. 
ACKNOWLEDGEMENTS 
The authors express their sincere gratitude to Director, NRSA 
and President, Technical Commission-VII, 2000-2004, ISPRS 
for his encouragement towards presentation of this invited 
paper during the ISPRS, Symposium, December 2002. Thanks 
are also due to Dr.T.Ravisankar, Scientist, Agriculture and 
Soils Group, NRSA for his technical help in preparing this 
manuscript. 
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