Classes Hectare %
Dense Forest 734.49 9.37
Less Dense Forest — 783.90 9,99
Bushes 1,862.19 23.75
Shrubs 1,103.58 14.07
Paddy Fields 621.36 7.92
Plantation 194.76 2.48
Other Agricultural — 2,508.30 31.98
Areas
Water Bodies 33.12 0.42
Roads
Streams
Settlements
TOTAL 7,841.70 100.00
4.2 Land Suitability maps :
Various land suitability analysis were
undertaken to output various land
suitability maps. These maps served as
input to the strategy formulation phase,
The processes involved called for land
suitability requirements for various crops,
for example, corn and sorghum, pasture,
paddy, mango, cassava and other root
crops. The FAO Framework for Land
Evaluation, 1976 was adopted based on
crop requirement parameters for each
ctop, and the four suitability classes were
defined, namely, *S1", the highly suitable
"S2", the moderately suitable, *S3", the
marginally suitable, and “N”, the not
suitable. Soil suitability maps for each of
the dominant crops in the area were
produce for further use as part of strategic
planning of the main project.
5. CONCLUSION AND
RECOMMENDATIONS
Remote sensing and geographic
information systems technologies were
used over a typical forest and agricultural
area aiming at a sustainable development
planning of the area under study. An
interdisciplinary — team effort was
employed and RS/GIS techniques were
used as one of the input into strategic
planning process. The contribution of
these technologies is indispensable,
especially when dealing with spatial
information over a large geographic area.
And, the manipulation of a large spatial
613
database can only be effectively done by
means of GIS.
There are a few recommendation points to
be made regarding the use of RS/GIS in
this study. Firstly, the classification
scheme adopted after US Geological
Survey which attempted to normalize
airphoto interpretation result and digital
classification of landsat TM data may not
be accurate enough to be accepted as final
result. A more acceptable common means
should still be sought. The use of FAO
Framework may be straight forward, but
the parameters used as input into the
process should be carefully picked, and
weighting or scoring of each parameter
should be carefully adjusted. A
disciplinary understanding of specific
processes would be required in this matter.
6. ACKNOWLEDGMENT
The authors express their sincere thanks
for the cooperation and assistance from
Drs. Apisit Eiumnoh and T.B. Suselo, and
the “1994 Practicum Team” from the
Asian Institute of Technology, Bangkok,
Thailand. And, last but not the least,
members of staff of Remote Sensing
Laboratory (RSL) of AIT for the
assistance rendered in the laboratory and
related work.
7. REFERENCES
Andersson, J.R. et al. 1976, A Land Use
and Land Cover Classification System for
Use with Remote Sensor Data,
Geographical Survey Professional Paper
964, pp. 13-16, USA.
Anuta, PE. and R.B. McDonald 1971.
Crop Survey from Multi-band Satellite
Photography Using Digital Techniques.
Remote Sensing of Environment, vol. 2,
pp. 53-67
Aronoff, S. 1989. Geographic
Information Systems : A Management
Perspective. WDL Publications, Canada
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996