In: Stilla U, Rottensteiner F, Paparoditis N (Eds) CMRT09. IAPRS, Voi. XXXVIII, Part 3/W4 — Paris, France, 3-4 September, 2009 
attributes can be used, e.g. mean values, standard deviations, 
texture and shape of the segments. The method automatically 
selects the most useful ones for classification. In the Marseille 
area, the criteria selected in the tree included only the NDVI. In 
the Lyngby area, NDVI and a shape attribute were selected. The 
third stage consists of a post-processing step that analyses the 
size and neighborhood of building segments and corrects their 
class accordingly. Building detection results in a building label 
image which is used for the comparison in our test. 
Olsen and Knudsen, 2005: The input of the method is given by 
a DSM, CIR orthophotos and a raster version of the outdated 
database. The method starts with the generation of a DTM, 
estimated from the DSM through appropriate morphological 
procedures, a nDSM and an Object Above Terrain (OAT) mask. 
This is followed by a two-step classification that aims at 
distinguishing building from no building objects. This 
classification is based on criteria that best characterise buildings 
(especially in terms of size and form) and results in the building 
label image that is used for the evaluation in this study. The last 
stage is the actual change detection step, in which the 
classification outcomes is compared to the initial database in 
order to extract a preliminary set of potential changes (on a per- 
pixel basis) that is then post-processed in order to keep only the 
objects that are assumed to have changed. 
Rottensteiner, 2008: This method requires a DSM as the 
minimum input. Additionally it can use an NDVI image, height 
differences between the first and the last laser pulse, and the 
existing database, available either in raster or vector format. The 
workflow of the method starts with the generation of a coarse 
DTM by hierarchical morphological filtering, which is used to 
obtain a nDSM. Along with the other input data, the nDSM is 
used in a Dempster-Shafer fusion process carried out on a per- 
pixel basis to distinguish four object classes: buildings, trees, 
grass land, and bare soil. Connected components of building 
pixels are then grouped to constitute initial building regions and 
a second Dempster-Shafer fusion process is performed on a per- 
region basis to eliminate remaining trees. Finally, there is the 
actual change detection step, in which the detected buildings are 
compared to the existing map, which produces a change map 
that describes the change status of buildings, both on a per-pixel 
and a per-building level. Additionally, a label image 
corresponding to the new state of the data base is generated. In 
spite of the thematic accuracy of the change map produced by 
this method, it was decided to use this building label image for 
the evaluation in this test. 4 
4. EVALUATION AND DISCUSSION 
In our opinion, the effectiveness of a change detection system is 
related to its capacity to guide the operator’s attention only to 
objects that have changed so that unchanged buildings do not 
need to be investigated unnecessarily. These considerations 
result in the evaluation criteria used in this paper to analyze the 
change detection performance. On the one hand, to support the 
generation of a map that is really up-to-date, i.e. to be effective 
qualitatively, the completeness of the system for buildings 
classified as demolished and the correctness for unchanged 
buildings are required to be high. The completeness of new 
buildings also has to be high if the operator is assumed not to 
look for any new building except for those which are suggested 
by the system. (Note that this also holds true for modified 
buildings, a case not considered in this study because the 
simulated changes only consisted in new and demolished 
buildings). On the other hand, to reduce the amount of manual 
work required by the operator i.e. to be effective economically, 
the correctness of the changes highlighted by the system and the 
completeness of unchanged buildings must be high. However, if 
a low completeness of unchanged buildings implies that many 
buildings are checked uselessly, this is not necessarily critical 
for the application itself, because the updated database is still 
correct. Moreover, the economical efficiency that could then 
appear to be low has to be put into perspective according to the 
size of the building database to update. For instance, if a change 
detection system reports 60% of a national database as changed, 
we cannot necessarily conclude about the inefficiency of this 
system because it still means that 40% of the buildings need not 
be checked, which amounts to millions of buildings. 
4.1 Overall Analysis 
Figure 1 presents the evaluation of the results achieved by the 
methods that processed the Lingby test area (LIDAR context). 
Table 1 gives the per-building completeness and correctness, 
obtained for each test area and each approach. The 7), parameter 
(cf. Section 2.) was set to 0.20 for the Marseille and Lyngby test 
areas and 0.26 for the Toulouse test area. In Table 1, the values 
in bold indicate for which methods the best results are achieved. 
The completeness of detected changes is high for all the 
methods, especially in the aerial (Marseille) and LIDAR 
(Lyngby) contexts. By contrast, the correctness observed in our 
experiments is relatively poor, which indicates that there are 
many FP changes reported by the systems. In this respect, only 
the results obtained in the Lyngby test area with (Rottensteiner, 
2008) seem to achieve a relatively acceptable standard. 
Approach 
Completeness 
Correctness 
Marseille (Imagery - Aerial context) 
(Champion, 2007) 
94.1% 
45.1% 
(Matikainen et ah, 2007) 
98.8% 
54.3% 
(Rottensteiner, 2008) 
95.1% 
59.1% 
Toulouse (Imagery - Satellite context) 
(Champion, 2007) 
78.9% 
54.5% 
(Rottensteiner, 2008) 
84.2% 
47.1% 
Lyngby (LIDAR context) 
(Matikainen et ah, 2007) 
94.3% 
48.8% 
(Olsen and Knudsen, 2005) 
95.7% 
53.6% 
(Rottensteiner, 2008) 
91.4% 
76.1% 
Table 1. Completeness and Correctness achieved by the four 
algorithms for the three datasets. 
To take the analysis further, we also determined the quality 
measures separately for unchanged, demolished and new 
buildings. They are presented in Tables 2 (Marseille), 3 
(Lyngby) and 4 (Toulouse), respectively. Focusing on the 
Marseille test area first, it can be seen in Table 2 that all 
algorithms are effective in detecting the actual changes. Thus, 
(Matikainen et al., 2007) and (Rottensteiner, 2008) achieve a 
completeness of 100% for demolished buildings. The 
correctness for unchanged buildings is also 100%. The few 
(11.1%) demolished buildings missed by (Champion, 2007) are 
caused by extracted primitives that are erroneously used in the 
verification procedure. All three methods also feature a high 
completeness for new buildings. Here, (Matikainen et ah, 2007) 
performs best, with only 2.4% of the new buildings missed. The 
main limitation of this context appears to be the poor 
correctness rate achieved for demolished buildings, which