is suggested that ~200 laser altimetry sensor may be required to 
fulfil the demand. At current growth rates, this base will not be 
fully installed until 2005. 
Such analysis is an important factor for any forward-looking 
estimate of the impact of airborne laser altimetry on the 
commercial remote sensing industry. It provides a view of what 
the competitive sector will look like for survey companies 
offering laser altimetry services, especially if further reductions 
in the barriers to entry are considered. It can also provide a 
basis for future production capacity planning. 
5. ACKNOWLEDGEMENTS 
The author would like to acknowledge the following people for 
providing historical data and projections as well as related 
information, insight and suggestions: Dan Cotter (TerraPoint), 
Stephen DeLoach (EarthData), Robert Eadie (EagleScan), 
Robert Fowler (LaserMap Image Plus), Peter Fricker (LH- 
Systems), Nigel Gardner (Laser Mapping Specialists), 
Christoph Hug (GeoLas), Ron Roth (Azimuth), Hakan Sterner 
(TopEye), Stewart Walker (LH-Systems). 
6. REFERENCES 
Ackermann, F., 1999. Airborne laser scanning - present status 
and future expectations. ISPRS Journal of Photogrammetry 
and Remote Sensing, 54(2/3), 64-67. 
Baltsavias, E.P., 1999a. Airborne laser scanning: basic 
relations and formulas. ISPRS Journal of Photogrammetry 
and Remote Sensing, 54(2/3), 199-214. 
Baltsavias, E.P., 1999b. Airborne laser scanning: existing 
systems and firms and other resources. ISPRS Journal of 
Photogrammetry and Remote Sensing, 54(2/3), 164-198. 
Blair, J.B., Hofton, M.A., 1999. Modeling laser altimeter 
return waveforms over complex vegetation using high- 
resolution elevation data. Geophysical Research Letters, 
26(16), pp. 2509-2512 
Blair, J.B., Coyle, D.B., Bufton, J.L., Harding, D.J., 1994. 
Optimization of an airborne laser altimeter for remote 
sensing of vegetation and tree canopies. Porc. Int. Geosci. 
Remote Sens. Symp. II, pp. 938-941. 
Bufton, J.L., Garvin, J.B., Cavanaugh, J.F., Ramos-Izquierdo, 
L., Clem, T.D., Krabill, 1991. Airborne lidar for profiling 
of surface topography. Opt. Eng. 30, 72-78. 
Flood, M., 1999, Review of airborne laser technology. EARSel 
Newsletter, June 1999, pp. 20-23 
Flood, M., Gutelius, B., 1997. Commercial Implications of 
Topographic Terrain Mapping Using Scanning Airborne 
Laser Radar. Photogrammetric Engineering and Remote 
Sensing, 63(4), pp. 327-329 and 363-366. 
International Archives of Photogrammetry and Remote Sensing, Vol. 32, Part 3W14, La Jolla, CA, 9-11 Nov. 1999 
    
  
  
   
    
   
    
   
    
   
  
    
    
   
   
   
   
    
  
   
    
   
  
    
   
    
   
    
   
    
  
  
  
  
  
  
  
  
  
  
  
  
  
  
    
Fricker, P., 1999. Product Manager, LH-Systems. Personal 
correspondence. 
Gutelius, B., 1998. Engineering applications of airborne 
scanning lasers; reports from the field. Photogrammetric 
Engineering and Remote Sensing, 64(4), pp. 246-253. 
Huising, E.J., Gomes Pereira, L.M., 1998. Errors and accuracy 
estimates of laser data acquired by various laser scanning 
systems for topographic applications. ISPRS 3. 
Photogramm. Remote sensing 53(5), pp. 245-261. 
Krabill, W.B., Collins, J.G., Link, L.E., Swift, R.N., Butler, 
M.L., 1984. Airborne laser topographic mapping results. 
Photogrammetric Engineering and Remote Sensing, 50(6), 
pp. 685-694. 
Kraus, K., Pfeifer, N., 1998. Determination of terrain models 
in wooded areas with airborne laser scanner data. ISPRS J. 
Photogramm. Remote Sensing 53(4), pp. 193-203. 
Walker, S., 1999. Director of Marketing, 
Personal correspondence. 
LH-Systems. 
Wehr, A., Lohr, U., 1999. Airborne laser scanning - an 
introduction and overview. ISPRS Journal of 
Photogrammetry and Remote Sensing, 54(2/3), 68-82.