International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
have a distinct stepped appearance with the white points lying 
well in front of the plane and the black points well behind the 
plane. In the corrected point cloud this stepped pattern has been 
flattened out. 
  
  
  
  
  
Fig 11: Corrected colour chart points 
In practice the range correction can be applied after the data has 
been captured by the scanner, so that a correction for each 
scanned point location can be computed. Ideally the correction 
factor should be applied to the data within the scanner. 
Further correction factor considerations 
1. The correction factor was formulated for a limited 
range (4 to 5.5 metres). It was noted during this 
experiment that there appeared to be different 
regression curves for different bands of ranges. This 
assumption should be tested further. 
2. Neutral 8 grey was selected as the optimum colour in 
terms of reflectivity. 
3. It is possible that this correction factor will be 
different for individual scanners using similar range 
measurement methods. 
CONCLUSIONS 
It is known from practical experience with the 2500 laser 
scanner that materials of different colour and texture produce 
point clouds of varying quality. At Plowman Craven and 
Associates (PCA) the scanner is being applied to projects 
demanding greater accuracy where errors imposed by different 
materials may be significant. It is therefore important to 
understand where possible erroneous points may be found in 
order to be able to evaluate and make use of the resulting point 
cloud in an effective manner. 
Prior to these experiments it was assumed that point cloud data 
representing different coloured surfaces would vary in density 
and data quality according to the surface properties at the 
scanner laser wavelength. This paper has demonstrated that, 
over the limited range of test distances investigated, the noise 
within each dataset to orthogonal surfaces appeared random and 
largely insensitive in terms of distribution and data density to 
variations in surface reflectivity. Significant differences were 
however found when the planar colour chart was rotated by 
angles of up to 60 degrees to the scanner. In such cases the 
spread of the data distribution actually improved with scan 
angle. Unfortunately at 60 degrees the density of the point data 
began to noticeably decrease making angles of 40 degrees more 
practical. 
Experimental results demonstrate a systematic discrepancy in 
range recorded by the scanner to different colour patches. 
Results agree with the expectation that colours with a poor 
reflectance at 532nm, for example black and red, reflect less of 
the laser pulse causing the scanner to record a greater range than 
the true position. Furthermore the observed difference in range 
between colour patches closely correlates with the data point 
measurement quality value recorded by the 2500 scanner. This 
correlation appears stratified into groups of different ranges 
which is likely to be related to the manufacturer's scanner 
calibration methodology. A correction factor was formulated for 
ranges of 4 to 5.5 metres and applied to selected colour patch 
datasets to produce a set of corrected point locations. The 
correction was found to move 3D data points derived from 
different reflecting patches closer to physical location of the 
complete colour chart thereby enhancing accuracy. The 
correction did not improve the precision of the point cloud. 
It is likely that all scanners which use a similar method of range 
measurement will also exhibit variations in range when 
scanning a variety of different colours. It may therefore be 
preferable to incorporate an experiment testing the response of 
the scanner to a variety of colours as a standard part of a 
calibration procedure. A further paper is in progress which 
describes similar experiments undertaken to analyse scanner 
response to a selection of different material types at both close 
and longer ranges. 
ACKNOWLEDGEMENTS 
The authors would like to acknowledge the support of Plowman 
Craven and Associates Ltd (PCA) and the UK Department of 
Trade and Industry's Teaching Company Scheme without 
which this work would not have been possible. Equipment 
purchased as part of EPSRC strategic equipment funding 
(GR/R06878/01) supported these tests. 
REFERENCES 
1. Barber, D. and Mills, J. 2001. Redefining the three R's — 
Reflectance, Resolution and Reference: Important 
considerations for Laser Mapping Systems. Surveying 
World. May/ June. Pages 33-34. 
Johansson, M. 2002. Explorations into the Behaviour of 
Three Different High-Resolution Ground-Based Laser 
Scanners in the Built Environment. Proceedings of the 
CIPA WG 6. International Workshop on Scanning and 
Cultural Heritage Recording. Sept 1-2, 2002. Corfu, 
Greece. Pages 33-58. 
Lichti, D and Harvey, B. 2002. The Effects of Reflecting 
Surface Material Properties on Time-of-Flight Laser 
Scanner Measurements. Symposium on Geospatial 
Theory, Processing and Applications, Ottawa. 
4. Fryer, J.G., Parberry, R.D. & Robson, S., 1992. Analysis 
of as-built cylindrical shapes. Australian Journal of 
Geodesy, Photogrammetry and Surveying 56:91-109. 
n2 
“I 
5.  www.brucelindbloom.com A selection of useful Colour 
Calculators and Spreadsheets accessed July 2002. 
6. Tucker, C. 2002. Testing and verification of the accuracy 
of 3D laser scanning data. Symposium on Geospatial 
Theory, Processing and Applications, Ottawa. 
7.  Boehler. W, Bordas Vicent, M. & Marbs A. 2003. 
Investigating laser scanner accuracy. Presented paper XIX 
CIPA Symposium at Antalya, Turkey, 30 Sep — 4 October 
2003. 
  
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