The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part Bl. Beijing 2008
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containing description of the basic reference unit for
digitalization, photo interpretation and digitalization rules. Each
reference parcel has to have a unique code in the frame of whole
Turkey which can be automatically attributed by the GIS
software. Due to frequent changes of administrative ordering
within Turkey, unique code is derived from geographical
coordinates.
Next step was to test the usefulness and effectiveness of ortho
photos and the LPIS database to locate and define the
boundaries of the current year’s agricultural parcels used by the
farmers through consultation with the farmers on both pilot
areas. The main objective of the consultation phase was the
contact with the selected farmers and more specific to facilitate
the location of their used parcels on the orthoimages, register
them on LPIS database and to ask farmers to answer to a
submitted questionnaire. Some interesting statistical figures are
prepared as result of the consultation campaign, concerning
differences in the areas declared by the farmers and those
actually measured on the orthoimages. Following the
consultation with the farmers in the field the outputs of this
work was used in the database updating process.
Within the frame of the Project, a specific SW Turkish IACS
Demo Software (TIDS) was created for the demonstration and
simulation of selected IACS procedures. TIDS was one of the
basic outcomes of the project aimed to implement project data
for producing real results for IACS testing procedures in the
Tekirdag area and to train MARA staff for global IACS
procedures. Real geographical data, real data of farmers’
declarations and real on-the-spot control data are all integrated
within the SW. Any simulation allowed because the objective
was to produce real statistics about eligible land area and
declaration anomalies.
3. EXPLANATION OF METHODS
3.1. Imagery acquisition and orthophoto creation
Very high resolution (VHR) Ikonos satellite images with a
resolution (pixel) lm for the pilot areas were acquired from and
provided by INTA Spaceturk in the vast majority between
spring and autumn 2006.
For the creation of the orthophotos the Erdas Imagine software
was used. Every frame of acquired image was orthorectified
using the Ikonos model and the rational polynomial coefficients
(RPC) of the image. The precision of the RPCs was improved
by applying a second order polynomial adjustment using precise
ground control points (GCP). Sharp comers clearly visible in
the image and well identified in the field (mainly cross roads)
were selected to be measured in the field. In order to achieve a
homogeneous distribution of GCPs within each pilot zone, a
grid of 14 Km x 14 Km was used and one (1) GCP selected in
every cell of the grid. The selected GCPs were then measured
with geodetic GPS instruments to have a horizontal accuracy of
about 20 cm.
The digital vector elevation maps of 1/25.000 scale topomaps
were used to create the digital terrain model. The “create
surface” tool of Erdas Imagine was used to create the digital
terrain model (DTM) with 5m grid size.
The Ikonos level 2 scenes, with an average size of 300 km 2
were orthorectified using an average number of 20 GCPs per
scene. The average root mean square error xy (RMSE) value of
the orthorectification procedure obtained was <1,70 meters.
Orthorectified scenes were mosaiced to produce a single image
for each one of both provinces. In Tekirdag 44 scenes and 21
scenes in Agri were mosaiced. The “breakpoint color
balancing” tool of Erdas Imagine was used to balance the color
of all images in each province in order to produce a seamless
color image.
The control of the visual appearance of the orthoimages was
done by the optical verification of the images by experienced
operators. In cases that some areas were identified as
problematic in terms of visual appearance (as the phenomenon
of “pulled” / “multiple” idols or the presence of degraded or
“undulate” forms like “ghosting images”, “wavy features”,
“smears”), they were further investigated for their possible
causes and the orthorectifying procedure was executed again.
The control of the geometry precision of the resulted
orthoimages was realized with the use of independent control
points of higher precision than 1/3 of the required final
precision (2,5m RMS), The coordinates that resulted from the
measurements of independent control points were compared
with those that resulted from the measurements of the x,y
position of the relevant point on the orthoimages with a view to
calculate the relative statistical figures which determined the
level of precision of final products.
3.2. Selection of Reference Parcel:
Concerning the establishment of LPIS,, different reference
parcel options have been thoroughly assessed particularly in
terms of database homogeneity and compulsory use of GIS as
stipulated by EU legislation. These options are:
Reference Unit / User
Based
Description
Agricultural Parcel
One piece of land cultivated by one
farmer with a single crop or a group
of crops.
Farmers Block / JJqJt
One piece of land cultivated by one
farmer with one crop or group of
crops.
Physical Block
One piece of land with permanent
boundaries may contain several crops
and farmers.
Reference Unit / Owner
Based
Description
Cadastral Parcel
Piece of land with specific geometry
that belongs to physical or legally
iAentilg
Figure 1 Definition of reference parcels
Due to fact that cadastre is concerning property rights, cadastral
parcels may not correspond directly to the agricultural parcels
(the location is correct but the boundaries and the area of
cadastral and corresponding agricultural parcel they do not fit),
