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the highest resolution and quality possible in order that it could
be re-utilised and data restituted at various later stages for vari
ous purposes, including the on-going monitoring of the sites.
Thus the metric accuracy had to be very high as was also the
quality of the photogrammetry and the surface detailing using
laser scanning.
The MCR’s 3DID team was naturally aware that before digital
photogrammetry came into existence, surveyors had used
theodolites to provide an accurate reference measurement lattice
within which conventional film-based photogrammetry could be
utilised within acceptable metric error levels. A Theodolite
Total station registers 3 dimensional co-ordinates and is the
only tool that offers the possibility of maintaining overall preci
sion by using a closed-network system. This data can be read
up to an accuracy of 0.1mm. The Theodolite Total station is not
designed for creating virtual surfaces and contours, as are pho
togrammetry and laser scanning. However, as the most precise
instrument of the three mentioned, the co-ordinates gathered
from the theodolite total station may be used to consolidate all
the data generated by the other surveying tools The 3DID team
therefore resolved to use a theodolite to achieve five objectives:
a) To create a closed network providing an accurate frame
work against which the digital photogrammetry could be
tacked on and measured
b) To set-up a one-stop target regime that can be utilised by
both photogrammetry and laser scanning ;
c) To laser scan the temple site using the same targets left in
an identical position when previously used by the
theodolite and the digital photogrammetry.
d) To take the results produced independently by the digital
photogrammetry and the laser scanning at the data acqui
sition stage and “marry” these results into one integrated
and composite image where the outlines are largely pro
duced using photogrammetry and the detailed surface im
aging is produced using laser scanning
e) To compare the results of the stitching of the laser scans
by the restitution software with those obtained by photo
grammetry in order to assess the levels of accuracy ob
tainable by the different systems independently;
Thus the concept of Thealasermetry 3 was bom: instead of using
two devices in synch 4 as proposed by Beraldin et. al., 3DID
opted for 3 classes of device used in conjunction - theodolite,
laser scanner and digital photogrammetry. The MCR team also
opted to run a series of tests in pilot sites in order to identify
other difficulties, strengths and weaknesses of the different
classes of devices being employed.
The Thealasermetry experiment was organised in the following
stages:
1. A sample survey at various grades of resolution of part of
the Ggantija temples in Gozo (December 2001) was under
taken to test the data acquisition capabilities of MCR’s
The reasons for coining the word Theodolite in have been lost in the
mists of time vide Alasdair Downes Q & A Theodolite
http://www.quinion.com/words/qa/qa-thel.htm Thea (Greek for
sight) is here being proposed together with lasermetry since all 3
systems are line-of-sight systems and many modem Total Station
Theodolites employ laser range-finding systems too.
I.e. a digital camera and a 3D range camera
SOISIC LG scanner and the restitution (including stitching)
abilities of MENSI’s 3D IPSOS Software;
2. A sample digital photogrammetrical survey(January 2002)
was carried out on the same part of the Ggantija temples
which had also been subject to a laser scan, thus providing
the basic data which would enable a test marriage between
the laser scan data and the photogrammetric data;
3. A sample laser scan at high resolution was carried out on
the Tarxien Temple altar at the National Musuem of Ar
chaeology in Malta (December 2001) in order to measure
the MENSI LG SOISIC scanner’s accuracy on an object
which is roughly the same size as that use for the Beraldin
case study;
4. A sample laser scan at various grades of resolution was
carried out on a non-megalithic monument (the crypt of St.
John’s Co-Cathedral in Malta) in order to evaluate other
system limitations that may be learned from different type
of architectural/archaeological applications;
5. A sample laser scan at various grades of resolution was
carried out at the San Salvatore Church in Kalkara (January
2002) in order to test operational advantages between the
MENSI LG SOISIC (plane triangulation) laser scanner and
the MENSI NG 100 time-of-flight laser scanner in prepara
tion for the Temples Survey Project;
6. A small-scale integration test was undertaken (March 2002)
combining photogrammetric data and laser scan data ob
tained from Ggantija, using the vector outlines obtained
from photgrammetry and the data from laser scanning to
provide the in-fill between the outlines;
7. A sample combined survey was carried out at a portion of
Tarxien Temples in Malta (June 2002) using the following
systems in combination:
a. Spheres with an integrated prism capable of being used
as a target by both the theodolite and the laser scanner
in quick succession without their being moved in the
process;
b. Theodolite Total Station to provide framework within
which to integrate data from digital photogrammetry
and laser scanner;
c. SOISIC LG Laser scanner to work in areas with range
2m-5m;
d. SOISIC NG Laser scanner to carry out fast scans to
compare results with those obtained from SOISIC LG;
e. Nikon D1 digital camera to provide digital photogram
metry data for back-office integration and restitution
process;
8. A large scale integration test of the data captured during
stage 7 was carried out (June 2002) using DIAP and 3D Ip-
sos software in order to repeat the successful integration
test carried out at stage 6 but this time on a larger scale and
with a clear view to minimising metric propagation error
having used the Thealasermetry process Stages 1 to 6 have
been successfully completed and will be fully reported upon
in this paper while parts of stages 7 & 8 were still work-in
progress at the time of going to press but will be completed
- and reported upon by the time the paper is due to be pre
sented at the September 2002 Corfu workshop.
