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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXX V, Part B7. Istanbul 2004 
  
  
  
  
  
  
  
. : greyscale) and used 
Classified Truth Sand Sand gravel | Clean gravel Cobble Pebble e as ian additional 
Sand +2 3 0 0 n/a layer to the three 
Sand gravel 10 45 5 0 n/a colour bands and the 
Clean gravel 5 21 x 27 n/a (ERDE layer used 
prior. Results 
Cobble 8 9 52 73 n/a indicated only a 
Pebbl 35 22 0 0 n/a modest 
  
  
  
  
  
  
  
Table 3 Percentages classified from three colour bands, texture 4- "similarity index" 
inevitably yield a range of particle types and hence, during 
accuracy assessment many pixels will. be identified as 
erroneous, when they actually represent valid particles. In 
addition, it should be recognised that true accuracies have been 
derived by comparing classified data with test areas not used for 
signature generation. Finally, the imagery was acquired in poor 
and overcast lighting conditions during light drizzle. In brighter 
weather, improved results may be obtainable: at least conditions 
were typical of mountainous environments! 
It is clear that a supervised classification based upon the three 
colour bands is inadequate, particularly for a five-fold 
classification. A three-fold classification into just sand, pebble 
and cobble was more successful (56%) but the more ambitious 
target was pursued. The classification is significantly enhanced 
by adding a “texture” layer, which implies that the spatial 
variability of signal response, rather than simply the colour 
characteristics of the pixels is important. An interesting variable 
in this context is the lithotype mix represented in the sediments 
with colour variation between clasts being important. It would 
be necessary to examine other field sites before this influence 
can be examined fully. The criticality of texture was expected 
given the relative roughness and hence shading-induced 
intensity variability of different bed material textures. Other 
authors have noted the significance of texture in related work, 
with Atkinson and Lewis (2000) reviewing "geostatistical" 
methods for classification and describing various alternative 
measures of "texture". These range from the statistics derived 
from the simple variance (Section 3. I) through to spatial auto- 
correlation (Section 4.1) and semi-variograms (Section 4.2) 
Which were investigated in this study briefly. 
4.1 Texture via spatial auto-correlation 
An additional avenue explored was the use of spatial auto- 
correlation to assist in the bed classification procedure. Rubin 
(2004) used spatial auto-correlation to derive correlation 
profiles between an original greyscale image of borehole-sand 
sections and the same image displaced by one, two, three and 
four, etc. pixels. The basic idea being that large particles exhibit 
high correlations for initial displacements, while. smaller 
particles generate low correlations for all pixel displacements. 
These basic differences generate contrasting correlation profiles 
which then vary spatially. Rubin (2004) then develops an 
empirical calibration function between measured sand grain size 
distributions and the correlation profiles that, it is claimed, can 
be used to identify sand grain size distributions for borehole- 
sand sections. 
The basic correlation algorithm was implemented in Matlab but 
tests revealed some concerns, particularly whether spatial auto- 
correlation can provide a good basis for measuring texture. An 
alternative approach was developed based upon the reciprocal 
of the summed variances between a 5x5 image patch and the 
same patch displaced by one pixel. This was adopted for bed 
classification using the 1:5000 orthophotos (converted to 
improvement (Table 
3. average success 
rate 51%), implying 
that very little new information was being added to the 
classification process and that the original texture layer was 
sufficient. : 
4.2 Texture via the semi-variogram 
Another approach investigated was the use of semi-variograms 
to perhaps provide an alternative measure of “texture”. Work 
conducted by Atkinson & Lewis (2000) and particularly Chica- 
Olmo and  Abarca-Hernandez (2000) advocated this 
geostatistical method most strongly. Their field of application 
was quite different, and involved the classification of 
Quaternary deposits using Landsat 5 imagery (Chica-Olmo & 
Abarca-Hernandez, 2000). Their results indicated an accuracy 
improvement of approximately 20% and the approach appeared 
promising. : 
|—e— LargeParticles | 
£— SmallParticles | 
Sand 
Semi-variance 
  
4 6 8 1 2 14 16 1 
Lag (pixels) where: pixel =8mm 9 
  
Figure 8- semi-variogram, 1:1,000, (NS) 
To investigate the technique semi-variograms were computed 
for three of the sub-areas (Dataset 3) labelled in the field as 
Sand, Gravel and Cobble. (Figure 8). This plot certainly 
suggests that production of a semi-varidgram could provide 
useful information for bed classification, with contrasting 
profiles being generated for the differing bed materials. 
   
  
  
  
500 m mt tete rte tort de si - ; 
| . —e— LargeParticles 
| a 400 ^. —8— Small Particles 
| o 
|.$300 Sand 
1.2 200 
TE 
| 9 199 
0 
2 4 6 8 10 12 14 16 18 
o 
Lag distance (pixels) where: 1 pixel 8mm 
Figure 9- semi-variogram, 1:1,000, ( EW) 
However, Figure 8 represents a North-South section through the 
semi-variogram surface, whilst Figure 9 represents an East-West 
section through the same surface. In this case there is not such a 
clear distinction in the profiles, particularly between the Gravel 
and Cobble sediment types. It is clear that semi-variogram 
direction is a critical controlling parameter with such an 
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