International Archives of the Photogrammetry, Remote Sensing
image areas sometimes single pixels are segmented
(comparable to the salt-and-pepper effect). The near infrared
was only marginally used in consequence of an unfavourable
especially the
weighting, which impacts separation of
deciduous vs. coniferous forest.
Figure 3. Segmentation result of the ‘Data Dissection Tools’.
CEASAR: The program CEASAR 3.1 which was developed
for radar data leads to results that cannot be used for further
processing (figure 4). The produced segments are compact and
of a similar size. This effect occurs even though using different
segmentation parameters which yield only to a varying average
segment size. Thus, small structures and in particular linear
elements are often segmented faulty and an over-segmentation
is the consequence. Boundaries of low contrast are represented
badly, sometimes boundaries of sufficient contrast too (e.g.
forest vs. meadow).
Figure 4. Segmentation result of CAESAR 3.1.
InfoPACK: The result of InfoPACK 1.0 (figure 5), the further
development of CAESAR, shows a good delineation for most of
the objects, but tends strongly to over-segmentation. Homo-
geneous areas are thereof less affected and are adequately
represented. In particular especially forests and built-up areas
were much partitioned. At land cover transitions often inter-
fering seam-forming segments were created. Generally low
contrasted boundaries were segmented correctly. Compact and
nearly similar sized segments as in CAESAR exist no longer.
For processing scenes of any size the software uses an imple-
mented tiling algorithm. Indeed this leads to additional segment
boundaries at the tile transitions. Furthermore margin effects
can yield to different results on both sides of the tile boundary.
As eCognition the software contains additional classification
and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004
tools. Thus, a classification based on merging of similar classi.
fied and neighbouring segments is possible and this reduces the
number of elements to be classified significantly. It must be
pointed out, that InfoPACK as well as CEASAR have been
developed to analyse very noisy radar data. Hence, the segmen-
tation of optical data could be suboptimal.
Figure 5. Segmentation result of InfoPACK 1.0.
Erdas Imagine extension *Image Segmentation': The Erdas
Imagine extension ‘Image Segmentation’ (figure 6) leads to
over- and under-segmentation within the same segmentation
result. Well-contrasted boundaries between main land cover
classes were correctly represented. Areas of low contrast were
often not segmented. In particular the delineation of fields vs.
meadow was problematic. Forested areas were merged into
large conglomerates, with small island segments inside only
slightly greater than the parameter minimal segment size
chosen. Linear elements were segmented inadequate and ho-
mogeneous image objects were divided frequently.
Furthermore, the result contains faulty segmentations in terms
of non-explainable horizontal or vertical boundaries. The
degree of this effect has been slightly reduced by a new version
from September 2002. It was mainly a consequence of the block
size used by the software, which can now be set freely in
accordance to the available system resources or the image size.
Thus, the computing time has been reduced too. But the
segmentation quality remained nearly unimproved.
Figure 6. Segmentation result of the Erdas extension ‘Image
Segmentation’.
‘Minimum Entropy Approach’: The ‘Minimum Entropy AF
proach’ (figure 7) was well reproducing straight boundaries 0
man-made features (e.g. field boundaries, roads). More complet
1100
Inte
natu
delit
neoi
the
foun
algo
Tesp.
inter
SPRI
algor
SPRI
Home
segm
segm.
the e
softw
shed-
(stron
evalu:
Segn
Num
areas
Aver,
area |
Aver:
perim
Aver:
Shape
Aver:
partia
|
Avera
evalu:
M
! differ
