R THE
hole complex of
he renovation a
ented it - at the
| of the fortress.
her maintenance
enovation of the
To record and
ompare it to the
ic recording was
bove downtown
) meters.
in the sense of
for scientific
ation in tourism
The Institute of Geodesy at University of Innsbruck, Austria
used some of the existing data and complemented it for
scientific interest with own measurements to extend the task
to
- combine different kind of basic data (metric analogue
and non-metric digital photos)
: combine and compare conventional restitution with
analytical plotter and digital restitution with low-cost
software
= extend the task to create a complete 3D-model of the
fortress
show the power of digital products to the public.
Beside the primary task to make a documentation of the as is
status of the buildings a second goal had to be taken into
account. The fortress is planned to be used as an arena for
cultural events such as operas, musicals and other
performances where the model can be used to plan the
seating for the audience and the lights and scenery for the
stage.
2. DATA SCOURCES
On the one hand a private surveying office in Austria - well
experienced in the task of documentation of cultural heritage
- has overtaken the job of fagade documentation by means of
analytical plotter leading to conventional facade plans. The
photos have been taken using a helicopter (see figure 2) and a
metric camera Zeiss UMK 10/13/18 to record the outer part
of the monument and the rocky hill on which it is based.
Fig.2: Zeiss UMK mounted in helicopter
—831-
About 180 metric images have been take from this helicopter
platform with an average overlap of 80%.
On the other hand a modern digital camera Olympus E 10
with a resolution of over 4 Million Pixel was calibrated and
used to record the interior and hidden parts. In addition to the
regular lens, which is build in the camera, a wide angle
adapter was used to achieve an all together focal length of
7mm (equals 28 mm with a small format camera).
This was necessary because from the helicopter it was not
possible to reach the interior parts as yards and paths within
the fortress (see figure 3)
Fig 3: digital photo of interior yard
Over 350 digital photos have been used to set up the 3D
model of the medieval fortress and to get good overlap even
in the “problematic parts” of the medieval fortress.
3. WORKFLOW OF THE RECONSTRUCTION
The process of object reconstruction for a virtual computer
model happens in 3 individual steps (for a detailed
description see Hanke, Ebrahim, 1999).
In the first step the camera's inner geometry, its position and
orientation during exposure as well as the objects’
characteristic wireframe and faces have to be reconstructed.
To get a consistent solution of the entire object these
elements are computed during a photogrammetric bundle
adjustment where a probable and homogenous result of the
whole measurement system is guaranteed. There is a large
number of photogrammetric systems available for this task,
ranging from very advanced to rather low-cost hard- and
software.
In the next step within a common CAD environment the
object's wireframe is reviewed and if necessary completed.
There also additional measurements (tape, theodolit, etc.) can
be introduced. After that the 3D model will be closed
defining faces between the structure lines. Subsequent it will
be investigated for leakage performing a first rendering
process. The surface model that arises during that step will be
used as a kind of "projection screen" and may have very
different level of details.
The third step is the actual retro projection of the photos (also
see Hanke, Ebrahim, 1996). Similar to a slide projector
selected photos are projected to the surface model using
raytracing techniques. The selection of photos is based on
visibility and projection direction. The "Digital Projectors"
