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CIPA 2005 XX International Symposium. 26 September - 01 October, 2005, Torino, Italy_
A traditional orhophoto was created on the other part of the park
(zone 2) using commercial software. The two products were
then put together, so the first 1:1000 scale orthophoto of the
Racconigi Park was thus created.
Figure 5. Zone 1 covered by a True Orthophoto
3. THE GIS
The so far described operations made it possible to obtain a
reliable geometric GIS base. A complete vision of the Park can
be achieved with this tool, which offers the chance of
overlaying different levels of information. The raw vector data
obtained from terrestrial and photogrammetric surveys were
edited (area reconstruction) and linked to the available
information, for example, the sketches of the network vertices.
The GIS environment was also supplied with products that are
able to integrate the Park and its historical evolution
description: the orthophoto, and the DEM.
Figure 6. The TIN of the Park built in the GIS environment
3.1 The Georeferencing of the Historical 1839 map
The GIS environment was a useful aid in the historical research.
In the hydraulic replanning of the park the Safeguard Office
decided to reconstruct the historic situation represented in a
1839 map as faithfully as possible. Using a rational function
deformation model, the different measurement units and the
deformation of the map were considered according to the age
and the digitalization process. The map was georeferenced by
selecting homologous points on both cartographic supports,
making the residual errors on the point less than 3.5 m; the main
difficulty was to find elements stable in time. Most of the
chosen points were fences and building edges and the main road
intersection.
3.2 The hydraulic replanning
The hydraulic simulation was carried out by a specialist team at
the Politecnico di Torino. The GIS environment was used to
derive the geometric model of the hydraulic network from the
survey supports. The canal edges were derived from the
overlapping of the actual geometries on the georeferenced
historic map in the GIS environment. It was attempted to
change the actual situation as little as possible; when in doubt,
e.g. for the width of the northern waterway that had to be
chosen, the GIS potentiality was applied to historical document
data. The archive research work in fact produced work reports
about the creation of some canals: in particular the length,
width, and depth of each part of the last expansion works. It was
therefore possible to reconstruct the geometry of these canals
from the document data: using the present northern waterway
centre line information and the excavation data, the width data
were placed on the actual map.
X
Figure 7. Matching of the photogrammetric vector layers on the
georeferenced historical map
Y Map
Residual X j
58817.188468
4.34625
58527 498421
3.64519
58665,764352
2.72271
59340.550007
0.81995
59316.226625
2.19777
50114.563865
2.56592
50113.366758
1.98242
60134.016864
7,13063
58240.491866
333769
58389.232439
3 58442
58629 551846
5.11801
58814.030261
0.69224
59168.250281
1.68408
59264.916723
1.25115
58918.054786
318180 v
. .
>
a! RMS Eira {3.44287
Figure 8. Map of the homologous points used in the
georeferencing, and the RMS error.
A good matching was observed between the present day
geometric information about the length of the northern
waterway and the archived excavation documents. This
interpretation work led to the design of today’s restoration
works done in that part of the park.
3.3 The evaluation of the volume that has to be moved
The GIS environment was also used to evaluate the volume of
earth that has to be moved in the restoration works. The
