ATA
jstruction
industrial envionments.
n to be able to model the
sses he semi automatic
ans taken from different
djustments. The method
leters are estimated from
re needed. A method to
t scans the registration is
we needed.
nbination of range data
> to be registered. In this
; capable of doing this.
ts measured in different
on parameters. In case
possible to register the
or cylinders are fitted in
an operator assigns
d objects. The last step
the registration of laser
it (ICP) algorithm (Besl,
responding points from
oresponding points a
s of this method are that
e data sets and that one
of the other. That is it
in both scenes, which 1s
rmore occlusions cannot
ne idea as ICP but can
ets of one another. This
ences by dynamically
en points throughout the
t designed to establish
tablish the relationship
ions on the surfaces
ier data set (Chen and
he techniques described
ages whereas (Eggert et
scans simultaneously.
/e, however, is designed
imultaneously, although
istration of 2D data and
Hanson, 1994)
The following section elaborates on the formulation of the
observation equations used to find the pose and shape
parameters of planes and circles in point clouds. Furthermore
the parameterisation of the objects is discussed. The third
section describes the mathematical model used to registerlaser
scan. In the fifth section initial results are presented.
2. FITTING OBJECT MODELS TO POINT CLOUDS
Before the registration can be started corresponding objects
need to be modelled in the different scans. Up till now
algorithms have been developed to fit planes (modelled as a
flat box) and cylinders to point clouds. The algorithms are
designed in such a way that the same ideas can be applied to
more complex CSG models. The principal idea is to minimise
distances from the points to the CSG model to be found by
adjusting the shape and pose parameters. The distance is
defined as the perpendicular distance from the point to the
object. For more complex CSG models this is not trivial to
calculate, however advanced 3D modelling software packages
offer this feature.
The specific changes between the observation equations of
different models lie in the fact that other partial derivatives
with respect to the shape and pose parameters are needed.
Section 2.1 gives observation equations for the fitting of a
plane. As this is a non-linear problem initial values are needed
for the pose parameters of the plane, which is described in this
section as well. Section 2.2. mentions the observation
equations to be used for cylinder fitting and describes a
method to find initial values for the shape and pose
parameters.
2. Plane
In close range laser scanning one has to take into account the
fact that planes can have any orientation when setting a certain
parameterisation whereas in aerial laser altimetry the data can
be seen as 2.5D in which vertical planes are not present.
Therefore choosing the right parameterisation
is important. Describing a plane by the normal vector and the
perpendicular distance from the origin to the plane (Figure 1):
provides a singularity free representation (Heuvel, 1999). A
plane can be written as a function of the normal vectorn and a
signed distance /,:
n-x—/ =0 (1)
Figure 1. Parameterisation of a plane by a normal vectorn and
a distance /,
Using this parameterisation the distances from a point j to a
plane defined by its normal vector n and the perpendicular
distance /,, can be calculated using:
d; Tp, ny, tnmx, Ex (2)
Where elements 7, n; and n; are the elements of the plane's
normal vector and elements x;, x, and x; are coordinates of the
point from which the distance is to be calculated.
The observation equations used are based on minimising the
distance from the points to the plane. The observation
equations that describe the relation between a change in the
distance and a change in the parameters is:
n
od
AP;
where Ad is the perpendicular distance from a point to the
object, p; are the object parameters, Ap; are the unknown
changes to the parameters and n is the number of parameters.
The partial derivative of the distance point p-plane with
respect to the rotation elements is:
b 4
On, tij (e
I
The partial derivative that describes the connection between
the perpendicular distance from the origin to the plane and the
measured distance is:
Before the iteration process can start approximate values for
the normal vector n and the distance /, of the plane have to be
available. As mentioned earlier the technique to find
approximate values is designed specifically for the use of
planes and will be different for other objects. The strategy to
find approximate values consists of two straightforward steps:
first an approximation of the normal vector is computed,
second the distance from the origin to the plane along the
normal vector is derived.
The normal vector of the plane is determined by calculating a
normal vector in each point of the plane. À normal vector in a
point is calculated by performing a nearest neighbour search
for the point p. In the next step vectors are calculated from
point p to the neighbouring points. In case the angles between
the vectors are sufficiently big the cross products are taken
between those vectors. The constraint on the angles is used to
reduce the effects of noise on the calculated normals. Finally
the average normal vector is taken as the normal vector at
point p. The normal of a plane is +n or —n. This is not a
problem when solving equations (3) as the plane’s distance
will have a different sign whether + or —n is used.
After the normal vector n of the plane has been
found the average distance is calculated from the distances
using:
1 N
L =y 2" x, (6)
j=1
in which N is the number of points used.
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