CIPA 2003 XIX th International Symposium, 30 September - 04 October, 2003, Antalya, Turkey
255
Airborne survey
It is traditionally associated with cartographic representation.
Today the distinction between cartography and architectonic
survey has many overlapping areas. One clear example is the
survey of paving at a 1:200 scale.
The survey carried out by the work group led by Professor
Carlo Monti (Milan Polytechnic) was made in large part using
aerial photoplans at a scale of 1:10000 and for the shady areas
with ground shots from scaffolding. The one hundred thousand
stones in the floor were rectified with an accuracy of ±3 cm.
In this case, the nominal scale is the same as architectonic
survey even if the technique and the representation are
cartographic.
Representation is a planimetry and not a plane which we know
is a horizontal section at a given height, while planimetry is a
view from above.
The survey of the floor takes its place among the other vector-
cartographic representations of the square: the City Technical
Map (CTC) is at a scale of 1:500 and the Regional Technical
Map (CTR) is on a 1:5000 scale. These are congruent with each
other since the CTR is obtained from a simplification of the
City Technical Map and therefore the metric accuracy of the
signs on a 1:5000 and is the same of the 1:500 scale.
The aforementioned maps are available for the square:
• 1:5000
It is thus possible to overlap the cartography described
previously and the DEM obtained by laser scanner (fig. 4).
It was interesting to note that despite the accuracy of the
altimetric data, about ±50cm, from a rapid elaboration and
using the Kriging algorithm for the gridding and therefore,
having generated the level curves, it was clear that the progress
of the square is characterised by its well-known "mule's
humps". From a comparison with the curves obtained with
trigonometric levelling, we found how the elaboration of the
laser data give optimal results.
It was decided to construct a true orthophoto of the area of the
Square. In the study, the 1:500 scale numerical cartograpy was
used for planimetric information and laser data for the
altimetry.
The existing numerical cartography was edited to extract four
different level of closed areas:
1. main pitches (main roof structure)
2. secondary pitches (garrets, etc.)
3. main streets
4. bridges, small narrow streets, etc..
Respect these different categories, the geo-referred laser data
was processed to obtain the dense DTM (18 cm) used as a basis
for realisation of a true orthophoto (fig. 5). The photograms
used were made by the CGR and supplied with the orientation
parameters registered during the flight.
• 1:500
• 1:200
all refer to the same reference system.
The first two are simply planimetric maps while the map on a
1:200 scale is three-dimensional. The altimetry of this latter was
integrated with the terrestrial measurements for trigonometric
levelling on a 4x4 regular grid, traced on the ground and
successively interpolated on a lxl meter grid.
The levelling served to realise profiles of the square at a scale
of 1:50 for the study of problems related to flood waters.
The DTM have given the level curves introduced in the
cartography. Thus, we were able to obtain a map at nominal
scale of 1:200 in planimetry and altimetry (fig. 1).
As regards the buildings that encircle the Square, we have no
altimetric data from the city and regional technical maps.
Therefore, these were integrated with ground measurements in
order to obtain a volumetric 3D model of the Square.
Recently a test flight from the CGR was realised with the
TOPOSYS laser scanner system that has supplied a new model
of the heights of the WGS84 reference system. The flight was
successfully georeferenced with respect to the national system.
—!■
fig. 4 Laser Scanner data elaborations (mesh and elevation curves)
