Full text: Proceedings, XXth congress (Part 2)

International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004 
  
  
3.1.1 Linear Local Context Object In order to fulfill 
the requirement of a general framework for describing con- 
text objects a generic class Linear Local Context Object 
has been defined. All local context objects are defined 
based on a common model; they just differ in the relation 
to the ATKIS object. The attributive description for any 
object defined in Linear Local Context Object is explained 
in the following: 
e width w(; and certainty width A... The local con- 
text objects are represented by means of the center 
axis. In order to be able to describe and assess topo- 
logic relations knowledge about the width and its cer- 
tainty is necessary. 
e certainty position projection AÂ,po: In this value the 
certainty regarding the position inherited by ortho- 
projection is considered: normally orthoimages are 
used which have been rectified using a terrain model, 
not considering objects above the ground (like trees 
and buildings). This leads to a position offset of those 
objects in the orthoimage, which has to be taken into 
account when topologic relations are assessed. The 
precise value of this offset is mostly unknown due to 
missing height information, but a range can be speci- 
fied. 
e certainty position algorithm A540: This value is sim- 
ilar to the previous attribute, but it emanates from 
the algorithm extracting the object (or more general: 
from the source of information): Often it is unclear 
how to fix the position of an object. For example the 
object Row of Trees is situated beside the road, i.e. the 
stems stand outside the carriageway. But in an aerial 
imagery one can just observe the crowns and is there- 
fore just able to make assumptions about the position 
of the stem. This assumption needs to be reflected in 
certainty position algorithm. 
e precision position and confidence: Refer to the gene- 
ral description of the quality attributes. In practice 
these measures are obtained for every algorithm indi- 
vidually, for example incorporating the pixel size and 
sub pixel accuracy for precision position. The confi- 
dence is obtained by applying an interior assessment 
of the results. 
One could also consider defining a Gaussian distribution 
for some measures defined as certainty above. If such a 
representation suits the requirements better has to be in- 
vestigated in the future. 
3.1.2 ATKIS Carriageway Object Regarding the AT- 
KIS objects the carriageway object is considered. In AT- 
KIS the carriageway is implicitly contained in roads and in 
objects of higher complexity such as highways. It can be 
easily derived from the standardized ATKIS road classes. 
The geometric description of carriageways in ATKIS con- 
sists of the center axis and the width, given as attribute 
(assuming a constant width). The width wA of an ATKIS 
object, its certainty A,, 4 as well as the nominal certainty 
of the position (A pA)! are given in the attributes of the base 
class ATKIS Carriageway Object. 
  
! Normally this value is Ay4 — 3m 
804 
3.1.3 Extracted Road Object In the relationship model 
a general class for extracted road objects is also present: £x- 
tracted Road Object. lts attributes are similar to the ones 
defined for the Linear Local Context Object, except for 
certainty position projection, this certainty is normally not 
of interest for roads as they are situated on the ground". 
3.2 Relations 
In the relationship model the geometric and topologic re- 
lations between an ATKIS object and the local context ob- 
jects as well as the extracted road objects are also given. 
It is important to note that the given relations are indepen- 
dent of any quality values: it is a general description of the 
reality. 
The geometric relation is parallel expresses the fact that 
in reality context objects are often parallel to road objects: 
For example in open landscapes elongated rows or trees 
are situated parallel to roads; in settlement areas the same 
holds for building rows. 
The topologic relation is important for this work as it must 
be taken into account that for example rows of trees must 
be situated outside the carriageway given in ATKIS whereas 
an extracted road (the surface of the road) must be con- 
tained in the ATKIS carriageway and the width of both ob- 
jects must be identical. The topologic relations considered 
so far are disjoint and contains. The latter one is defined 
relative to the ATKIS object. Besides this qualitative topo- 
logic relation one may define side conditions. For disjoint 
it is often desirable to give a minimum and a maximum 
distance (d. 1nin, d. max), which defines on the one hand 
an empty space between the road and the respective context 
object (d. mn) and on the other side some sort of influence 
border (d_max). For example a row of trees must have a 
minimum distance to the carriageway (due to security rea- 
sons) and also it is expected that trees having a distance to 
the carriageway larger than a certain value have no relation 
to the road. 
The topologic relation contains is for objects being situ- 
ated on the carriageway. The possible side condition for 
this relation is the indication that the width of both objects 
needs to be identical. This is important for extracted road 
objects. In Fig. 1 some object classes are derived from Lin- 
ear Local Context Object, but an extension to other objects 
is possible thanks to the common framework. The given 
side conditions for the topologic relations are chosen from 
experience, but the incorporation of prior knowledge from 
road planning instructions is also possible. 
4 STRATEGY FOR ATKIS ROAD ASSESSMENT 
AND IMPLEMENTATION 
In the framework of road assessment it is sufficient to de- 
fine a region of interest (ROI) for each ATKIS Carriageway 
Object-Segment including all extracted objects and to as- 
sess the given segment using these objects. The size of 
the ROI depends on the modeled relations as well as on 
the given quality measures: the worse the extracted data, 
the larger the ROI. As will be shown later the degree of 
support an extracted object gives for the assessment also 
depends on its quality. The strategy for road assessment is 
as follows: 
  
2Special cases such as road bridges not being present in the height 
model are for the moment not of interest. 
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