PI-7-3
3. ALGORITHM
Drainage Direction(flow direction) is set as the
steepest descent direction among the neighboring 8
direction by using DEM. The problem is that the
drainage direction can not be set at the concave pixel
or flat area as mentioned in above. In order to solve the
problem at concave pixel, a method increasing the
altitude of the concave point to make over-flow to
down stream is suggested and it is well
known(Nogami,1998). And for flat area problem,
some methods are reported to give certain drainage
direction for such pixels to reach to bottom of the
stream. In our experiences, if the target area covers
within a few sheet of 1:50,000 scale map and pixel
resolution is not more than 100m x 100m, the
automated extracted river system are very similar to
the reliable river system information, except Oat area
where the auto-extracted river line has a controlled
direction to the down stream, and the streams do not
run along the reliable stream lines in many cases.
In this study, global DDM is produced with 30 seconds
arc grid( about 1km resolution at equator) for lands. At
first, DDM was produced by using only GTOPO30,
correcting concave and flat area. It is confirmed that
most of computer extracted streamlines run in the
bottom of topography(valley) when it overlay with
shading image derived from DEM, and most of them
run along the streamlines of DCW and WBDb-II data
sets within several pixels distortion. However some of
the computer extracted streamlines have following
problems and the problems make the accuracy of the
DDM quite bad in some watersheds.
(1) For example, where three rivers - Yangzhu river,
Mekong river and Tanlwin river - run closely at south
of China, the computer extracted rivers make wrong
watersheds due to the confused DDM. It was easy to
detect such wrong river systems because the wrong
watersheds are enough big to detect. However similar
confusion must be happening in ¿mailer watersheds,
Fig.-l Extracted Watersheds comparing DCW data
