is fairly similar to the decimetre accuracy values quoted by 
authors such as Lohr (1998). 
One of the main error sources for planimetric accuracy was the 
planimetric shift observed between the LIDAR data and the 2D 
vector building outlines. In some cases the occurrence of roof 
edge pixels did not coincide with the building boundary and 
was often up to one pixel width outside that of the boundary. 
As Huising and Gomes Pereira (1998) admit this shift may be 
due to local factors such as planimetric building errors. The 
vector data used is claimed to have a planimetric accuracy of 
anything up to +/-1m. Systematic error may also cause a shift 
in building information. Shadowing resulting from low LIDAR 
scan angles (+/-19 degrees for this study) can be seen 
predominantly in the industrial area due to the high building 
sides hiding other building sections from the LIDAR sensor. A 
comprehensive guide of other error sources from laser scanner 
systems can be found in Huising and Gomes Pereira (1998). 
4.4 LIDAR and Roof Detail Extraction - Next Steps 
The use of relatively low resolution LIDAR data for roof detail 
extraction is restricted by the generalisation of roof structure 
information into grid cells. Mixed pixel effects created by the 
interpolation of the raw point data into a regular grid have 
contributed to increasing the difficulty with which roof detail 
can be extracted. One solution may be to use the raw data itself 
as demonstrated successfully by Maas and Vosselmann (1999). 
The processing of point data, however, tends to be a harder 
task compared to the simpler algorithms that are needed to 
manipulate grid data. Another solution could be to use a data 
set with a higher grid resolution derived from a higher point 
spacing. Increases in the level of roof detail may be possible 
with this higher resolution data, but the increases may not be 
sufficient enough to justify the higher cost of the data. 
Having discussed alternatives to the LIDAR data used in this 
study is not to say that it did not produce interesting results. 
The results derived from using the aspect parameter from the 
LIDAR data showed promising signs of being used as a useful 
indicator of the dominant ridges and segments of a building 
roof. There is the possibility that aspect could be used to define 
sub-ridges by splitting the roof aspect values into more than 
two groups. Some initial testing using four groups showed 
however that this produced poor results with the aspect groups 
imposing their own structure on the roof. 
Instead of trying to increase the amount of detail that can be 
extracted using this resolution data, a task which is unlikely to 
be successful, attention should be concentrated on using the 
available results for applications that require general roof 
detail. Applications such as virtual reality and the visualisation 
aspects of planning applications (Newton, 1996) which may 
require more than the basic rectangular block structure of a 
single height building, could use this level of roof detail. 
Higher detail 3D city models may be necessary to satisfy the 
publics inquisitiveness into the finer details of particular 
building construction schemes for example. 
  
   
  
  
  
  
   
  
  
  
  
   
  
  
  
  
   
  
  
  
  
   
  
  
  
  
   
  
  
  
  
   
   
  
  
  
  
   
  
  
  
  
   
  
  
  
  
   
   
  
  
  
  
  
  
  
    
International Archives of Photogrammetry and Remote Sensing, Vol. 32, Part 3W14, La Jolla, CA, 9-11 Nov. 1999 
After roof segmentation it is possible to extract height 
information for each new segment which could be used to 
update current 2D spatial databases with quantitative 3D 
information. A degree of semi-automation may be necessary for 
this process with the derived roof ridges acting as guidelines 
for the user’s own interpretation of the roof structure. 
5 SUMMARY AND CONCLUSIONS 
This paper has assessed the use of relatively low resolution 
LIDAR data for the extraction of roof detail from buildings, 
primarily for 3D city modelling. A 2D spatial database of 
vector building outlines was used to locate the roof extents. 
Two study areas were used to test the LIDAR data, an 
industrial area with large simple roofed buildings, and a 
residential area with smaller buildings and more complex roof 
structures. Through the use of LIDAR elevation, aspect and 
slope parameters, attempts were made to extract the main roof 
ridge of a building. Results suggest that it is possible to extract 
general roof detail using this data, especially for large buildings 
with simple roof structures. The aspect parameter performed 
best, extracting the largest majority of ridges from the 
buildings. Of these extracted ridges using aspect, just over half 
can be considered to be exact matches. In the residential areas, 
the smaller buildings and more complex roof structures made it 
much harder for the LIDAR data to produce meaningful roof 
detail. 
Other LIDAR data sets with similar or lower resolutions will 
most likely suffer the same problems experienced in this 
assessment. The vertical and planimetric accuracy levels of the 
LIDAR data are not conducive to the extraction of accurately 
positioned and located roof detail. The problems with the 
LIDAR data were substantial even though the buildings used in 
the study were chosen for their relatively simplistic structures. 
Despite these limitations, the level of roof detail extracted in 
this study is suited to several applications such as visualisation 
and spatial database updating. A semi-automated approach to 
roof detail extraction may need to be employed for these 
applications. The extracted ridges can be used as a guide for 
the user to better define the extent and nature of the ridges. To 
increase the amount of roof detail that can be extracted from 
this LIDAR data, the resolution, or rather the original point 
spacing of the LIDAR sensor, should be made more dense. 
This will, however, increase the cost of the data and make it 
less affordable to most laser scanner users. LIDAR data 
accuracy levels need to be improved further, as well as the 
relative accuracy levels between LIDAR data and any assisting 
data sets such as the 2D vector data set used in this paper. Until 
the use of higher density laser scanner instruments becomes 
more widespread and the cost of the technology decreases, 
relatively low resolution laser scanner data can be used to 
extract general roof detail from buildings. 
  
Internatio 
AC 
We would like to th: 
the Ordnance Surve 
Survey of Britain | 
Thanks to the Env 
LIDAR data. Resea 
available by the 
Nottingham. 
Axelsson, P., 1999 
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