International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part Bl. Istanbul 2004 
  
Type of parcel Topography 
Scale of the 
Variation of the 
  
orthoimage area between the extracted data and 
(9/0) the reference data (m) 
Rural — Large estates Flat terrain 1/10 000 0.14 : 4.3 
Rural — medium estates Rugged terrain 1/5 000 0.22 6.8 
(10 — 20ha) 
Rural — medium estates Rugged terrain 1/5 000 1.77 8.5 
(5 — 10ha) 
Rural — small estates Flat terrain 1/5 000 3.7 3.7 
(smaller than Sha) 
Peri-urban estates Flat terrain 1/2 500 22.6 4.33 
Urban estates Flat terrain 1/2 500 Do not apply Do not apply 
Mean variation of the distance 
  
Table 1. Results obtained for each type of properties. 
However some of the vertices have a difference of localization 
of less then one meter. 
There is a significant difference of result depending on the size 
of the property. Medium properties between 10 and 20ha 
presented a variation of surface of 0.22%, yet estates of 5 —10ha 
presented a variation of 1.77%. The difference of vertice 
location between the datasets was of 6.8m for properties of 10 — 
20ha. and of 8.5m for properties of 5 to 10 hectares. Field 
borders in rugged topography presented a very low density of 
vegetation, making the identification on the image more 
difficult (figure 4). When the border is under dense vegetation, 
the distance variation between the digitized border and the one 
survey can be as high as 11m (figure 5). In the case where no 
physical border exists the difference can be as high as 13m. 
Adding to this case, when there is no land use change, it is 
almost impossible to identify the border; the surveyor can only 
estimate the location of the vertice. 
For small estates in flat areas the variation of the area detected 
was of 3.7% and the average variation of the distance between 
the borders identified in the image and the survey one was of 
3.78m. 
4.2 Urban properties 
By peri-urban parcel, we consider properties of 500 — 1600m? 
with a combination of residences and survival cultures. Area 
variation was of 22.6% and the variation between borders was 
4.33m. Most of the cases presented no physical boundaries, 
only ‘legal invisible’ fences. The presence of fruit trees, make 
the identification less accurate as we had to generalize the 
location of the vertice under dense canopy. 
Where land consolidation is present, a variation of 1.48m of 
length is obtained. 
Urban identification on the orthoimage was limited as it can be 
observed on figure 6 and 7. The areas of the buildings surveyed 
were smaller than 500m?. The borders were barely identifiable 
in the orthoimage, making the delimitation of boundaries almost 
impossible. We have to note that building forms are highly 
changed between what can be identified in the image and the 
real aspect of the building as we can observe in figure 7. This is 
mainly due because of similar spectral response of the building 
and its entourage, where no contrast is identified the accuracy of 
image identification drops. Details of 8m of length could not 
be identified in the satellite image data. 
5. ANALYSIS AND DISCUSSION 
As.the area covered by the orthoimage is elevated and the use of 
digital data presents some advantages, different preliminary 
work can be done with the image. In this particular case, the 
use of satellite images can be implemented since the beginning 
of the cadastral activities, for example in: 
- planning activities, 
- preliminary analysis for the selection of methodologies to be 
used, 
- preliminary definition of cadastral polygons and municipality 
boundaries, 
- to update the cartography, and 
- for land-use/land-cover studies and general studies of the 
region surveyed. 
Nowadays in Guatemala, the planning of cadastral activities is 
made with outdated cartography, 1/50 000 maps and in many 
cases without any previous field supervision. The design of 
cadastral polygons is completed using official cartography and 
photogrammetric products from the 80' ad adjusted as the 
cadastral mapping advances. The delimitation of municipalities, 
which cadastral polygons cannot surpass, is done in a 
preliminary step with invalid maps and is adjusted on the field 
inspection making the planning step costly and time consuming.’ 
SPOT 5 orthoimage brings better elements than the ones used at 
the present . 
Eight GCPs were provided to relocate the image to a 2.5m 
spatial resolution of the orthoimage. Ideally a GCP should be 
as small as a single pixel and an appropriate number should be 
well distributed in the study area (Campbell, 1996, Korgaja et 
dl, 2003). In tropical woodlands, steep topography and for 
distant regions, to obtain appropriate GCPs is a challenging 
task. The nature of the study area will influence the 
georeferenciation of the orthoimage and the resulted accuracy 
border identification. 
The image used in this study presented some limitations, the 
presence of clouds and haze restricts the area of utility and the 
identification of parcel borders is more complex. It is 
recommended to work with enhanced images, as boundaries are 
most of the time linear, more easily identified. Depending on 
the average size of the properties, an adequate scale was chosen. 
Yet, as the image quality for cadastral mapping was not the 
most adequate one, most of the scaled images presented only 
the area of interest (cfr. Table 1). We cannot suggest an 
appropriate scale for preliminary or definitive cadastral plans, as 
the election of this one will depend on the nature and size of the 
properties — latifundium, medium and small estates, peri-urban 
and urban properties —, topography, atmospheric effects and 
precision needed. However, in this study we obtained more 
accurate results for medium scales (1/20 000 to 1/5 000) than 
for small ones (1/2 500), this is mainly due to the resampling 
method applied to the stereopair images of 5m spatial resolution 
to obtain a 2.5m orthoimage. 
As we can observe, the variation of the parcel area between the 
referenced data and the one derived form the image 
interpretation depends directly of the size and topography of the 
property. The variation of area was considered very low for 
latifundium estates with no topographic variation and for 
medium estates of 10 — 20ha. However, properties in rugged 
terrain, small agricultural estates and peri-urban properties 
   
      
    
   
  
  
  
   
   
  
    
    
   
  
     
      
     
    
  
  
   
   
  
   
   
    
    
   
  
  
   
  
  
  
   
    
  
   
  
   
    
    
   
  
  
  
  
   
  
  
  
  
  
  
    
   
   
  
  
   
  
  
   
   
    
   
    
   
   
   
    
   
  
   
  
   
  
       
   
  
   
   
    
   
  
Inter 
— 
prese 
variat 
land « 
For I: 
variat 
extra 
image 
rugge 
variat 
live | 
locate 
with 
bounc 
legal 
areas 
plant: 
The 
numt 
prese 
ident 
bounce 
less a 
accid 
cover 
be lin 
The 
meth 
prope 
medi 
urbar 
impoi 
their 
urban 
areas 
dense 
limite 
data 
logis! 
estim 
sourc 
resol 
time 
photo 
from 
exam 
most 
And 
comb 
ident 
As 1 
ident 
8.5m 
diffei 
the u: 
meas 
meas 
Fisca 
Poly 
the d 
for le 
is 0. 
toler: 
diffe; 
for 1 
toler: 
foru 
diffe: