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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
applications would like to better focus on problems and 
advantages of laser scanning technique applied to geological 
sites survey and monitoring. 
2. LASER SCANNING SURVEY OF A GEOLOGICAL 
SITE 
The acquisition of the point-cloud describing the surface of a 
slope which has to be investigated is carried out by a long-range 
TLS from a single or from multiple stand-points. All scans 
acquired from different positions must be fused together, 
transforming their coordinates into a unique reference system 
(registration). Very often surveys of geological sites require to 
be inserted into a pre-defined ground reference system (GRS), 
in order to compare data acquired at different times 
(monitoring) or for the georeference into a cartographic system. 
The setup of the survey's workflow stricly depends on 
characteristics of TLS, registration technique, dimensions of the 
site, required data accuracy and resolution. In the following 
some of these aspect will be analyzed in detail. 
2.1 State-of-the-art of long-range TLS 
A long-range TLS (LRTLS) should allow the acquisition of 
points belonging to a surface at a distance of several hundreds 
metres from the stationing position. Upgraded technical features 
of current available instruments can be found at websites of 
constructors (see References from Websites). 
The common measurement principle of all TLS is the time-of- 
flight method, the unique which permits long range 
measurement in a fast time. More recent instruments are 
equipped by a digital camera as well, which may collect images 
to be used for generating orthophotos or realistic Virtual Reality 
models. 
Almost all current LRTLSs present some facilities which can be 
very helpful in practical surveys, such as the possibility of 
controlling the acquisition process by means of a laptop or a 
palm PC, also via remote wireless connection. 
From a logistic point of view, in geological surveys the 
transportability of the instrument and its accessories (tripod, 
energy unit, PC) is fundamental, because might easily happen 
that arduous stand-points have to be reach. However, many 
efforts are required in the future to reduce weight and 
dimensions of LRTLSs. 
2.2 Registration of views: different approaches 
Concerning strategies for registering multiple scans, two 
different approaches can be followed. In both cases, a set of 
ground control points (GCPs) is needed to register the point- 
cloud to a given GRS. As GCPs may be used refro-reflective 
targets or common features which are well identifiable in the 
scans. Which method is available strictly depends on the TLS 
and particularly on the data processing software being used. 
Normally only one option is possible. 
2.2.10 Fully GCP based registration: In case enough GCPs 
are available in each scan, these can be straight-forward 
registered to the given GRS. From a mathematical concern, this 
task consist in computing 6 parameter of a rigid 3D roto- 
translation from the intrinsic reference system (IRS) of each 
3D-view to the GRS. 
709 
Although this method is largely reliable and leads to a high 
accuracy in the registration process, sites which are surveyed 
for geological purposes may present a very complex 
morphology, which makes difficult, if not impossible, to carry 
out topographic measurements of GCPs. This drawback may 
results in a longer survey times and decreases the avantage of 
using a TLS in many applications. 
On the other hand, if different 3D-views share a sufficient 
portion, GPCs can be positioned to serve more than one model. 
Moreover, if the TLS features a large horizontal FoV, GCPs can 
be also external to the area to be acquired. 
Usually, the minimum number of GCPs needed to register a 
3D-model is 3, but practically a higher one may be required, 
according to the algorithm used to compute the initial values for 
the roto-translation parameters (equations are not linear); in 
literature a large variety of methods to solve for these 
approximations can be found (see Gruen & Akca, 2004). 
2.2.2 Pairwise registration techniques: A second 
possibility of georeferencing different 3D-views arises in case 
GPSs are not visible in all of them. In this case the available 
methods are based on the pairwise registration of scans, starting 
from a 3D-view which is chosen as reference and registering to 
it all the other 3D-views sharing a sufficient number of tie 
points (TPs). Then, neighbouring scans are registered as far as 
the whole block is oriented. As tie points, in geological 
applications retro-reflective targets have to be preferably used, 
because their measurement can be performed with the higher 
accuracy either by automatic and manual procedures. Methods 
based on automatic extraction of not-signalized tie points (see 
Gruen & Akca, 2004 for a review) or directly on matching 
corrisponding surfaces are very usefull in architectural and 
mechanical applications, but they do not hold yet in the 
geological field, where the presence of not coherent terrain and 
of moveable objects (rocks, vegetations, ...) can lead to errors in 
registration. After pairwise registration of all 3D-views to the 
same “project” reference system (PRS), thank to a set of small 
GCPs the point-cloud can be transformed into the GRS. 
In Scaioni & Forlani (2003) a procedure has been proposed to 
solve for a simultaneous block triangulation of all models, using 
as constraint only a small set of GCPs. This approach (or 
another similar) can be usefull if in the interested area GCPs 
cannot be directly measured, being only possible to put TPs. 
2.3 Survey planning 
The planning of a landslide survey usually suffers from the 
typical problems involved in a traditional photogrammetric 
survey: several factors must be considered, so that standard 
design methods are not so easy to be established, as happens for 
flight plans in aerial photogrammetry. Nevertheless, a limited 
effort has been produced so far in order to give at least some 
basic addresses for a correct survey planning. 
The strategy we followed is based on establishing a set of 
simplified relations which can be used to setup a TLS survey. 
Topics decision that have to be made are the following: 
e selection of the more suitable TLS model (if possible); 
® position and number of TLS stations; 
e strategy for 3D-views registration, resulting in 
positiong and measurement of GCPs. 
Input data for the survey design are basically the resolution and 
the accuracy of the point-cloud describing the surface to