3. PRODUCTION OF THE MODEL INPUT DATABASE
The production of data for use as input to the
erosion risk model can be separated into three
main sources of data : thematic maps,
topographic maps and remote sensing. All these
data were converted into a common form using
the PC based ICONOCLAST Image Processing and
Spatial Information System, developed by Image
Technology Systems Ltd.
Prior to the digitisation process the effective
scale of the required data was chosen. As the
input to the model and manipulation of these
data is essentially a grid cell (raster based), the
size of the cell is the major factor. This was
chosen to be 150m, giving a thematic database of
500 x 700 cells (pixels).
3.1. Thematic Maps
The production of the thematic map database
produced inputs related to the resitance of soil
to erosion, namely the Geology and Soils of the
region.
Digitisation of soil and geology class boundaries
was achieved using both a digitising tablet, and
a process of video digitisation and boundary
extraction. Both resulted in a class boundary
vector database extracted in the pre-defined
co-ordinate system.
The boundary data from various mapped sheets
was then aggregated and any map sheet edge
problems resolved. The boundaries were then
used in a graphical seed fill process, thus
converting each pixel within a boundary to a
pixel value indicative of class. The boundaries
are then removed by a process of line
replacement from adjacent pixels.
In this type of raster based Spatial Information
Systems, pixel brightness is related to a table
describing class attributes. Thus to obtain the
class of any pixel is a simple case of looking up
the class table. The location and topology of each
pixel is only known from its position in the grid.
A number of other thematic databases where also
created at this stage to assist in future work.
These included Land Management Units, (official)
Land Use and Stream Sub-catchments.
3.2. Topographic Maps
Given that slope and slope length, aspect and
elevation are important considerations in the
model a digital elevation model (DEM) had to be
constructed. In may parts of the developed world
DEM are commercially available, for developing
countries this information is often restricted. It
is therefore necessary to have tools for
generating a DEM from any available data. For
the study area large scale topographic maps
were not available, due to government
restriction, and an alternative source of data was
needed. Tactical Pilotage Maps are generally
available worldwide and this was used as a
source of all topographic information for the
study.
Individual section of the pilotage map were
raster digitised at high resolution to facilitate
the extraction of contour data. All relevant
contour information was extracted by a manual
process of on-screen digitisation - an extremely
laborious task. Other topographic features such
as roads, built areas and the drainage network
were also extracted to assist in the geometric
rectification of the remote sensing input.
The elevation data consisting of contours and
spot heights was then converted to a raster
representation of height by an interpolation
process. A number of methods were tested
including various Least Squares (Jancaitis and
Junkins, 1973) and Multiquadric (Hardy, 1971)
procedures. Later work suggested the more
efficient use of triangulation routines.
Given a satisfactory raster representation of
elevation, where pixel brightness is directly
proportional to height, slope, aspect and other
related measures can be derived. The algorithm
used for generation of slope and aspect for the
model was a modified version of the algorithm
developed by Ritter (1987).
3.3. Remote Sensing
The difference between land use detailed on
available maps and actual land use was
considered to be significant; particularly in
upland areas where considerable de-forestation
had occurred. Satellite remote sensing was seen
as a means of providing up to date land use
information at sufficient scale for use in the
model.
A Landsat MSS scene was acquired and
subsequently used to produce a land use map
using multi-spectral classification techniques. A
1536 x 1536 extract was taken from the full MSS
scene. This was first used to define a number of
ground control points using on-site experience
and the topographic map.
The extract was then corrected to the database
co-ordinate system, primarily for use as a
frontispiece in a report overlayed with
topographic features and catchment boundaries.
What is also extremely evident on this image is
the siltation of the reservoir compared to the
downstream irrigation channel.
The extract was then used to define training
areas for land use. Training statistics were
produced and used in a Maximum Likelihood
classification of the extract. The accuracy of the
classification was visibly checked for a further
set of areas for which ground truth was known.
In light of the available alternative, and
subsequent empirical processes involved in the
model, the classification was considered to be
sufficiently accurate and the classification was
then corrected to the database co-ordinate
system.
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