International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004 
  
area surveyed, average canopy height was about 45 meters and 
tree density about 280 stems/hectare. 
Two points should be noted: (1) there appears to be little mean 
offset irrespective of the tree density which implies that the at 
the sub-meter level, the ground is being detected, and (2) the 
RMSE grows with increasing tree density from about 1.3 meters 
to 3.3 meters. 
Similar lidar comparisons with truth indicated a bare lidar 
RMSE of 0.5 meters in the uncut stand. This enables us to use 
the lidar results with some confidence over the remainder of the 
area. |n Figure 9 we summarize the (P-Band — Lidar) 
differences for various tree height classes and for three slope 
classes. We note that the tree height estimates are based upon 
(X - P) height differences, which will therefore underestimate 
the true heights as noted earlier. Moreover, they are likely to 
underestimate the true heights increasingly as tree density is 
reduced. This is not accounted for in this figure. The major 
points to be observed are: 
(1) (P-Band DTM - Lidar) RMSE increases with tree 
height (from 1.6 to about 3.2 meters for moderate 
slopes) with the larger error corresponding to tree 
heights (after correction) greater than 45 meters. 
2) (P-Band DTM - Lidar) RMSE increases with slope 
for all tree height classes ( by 30% - 50% for the 
largest slopes. 
(3) These results are consistent with the ground survey 
results 
(4) Although not shown here, there is no consistent mean 
offset that is dependent upon tree height. However 
there appears to be a persistent increase of mean 
offset with increasing slope. 
  
P-Band RMSE vs. Tree Height 
BSlope « 10* 
910" « Slope « 20" 
OSlope > 20° 
(P-Band ~ Lidar) RMSE (m) 
   
  
  
15-25 
Tree Height (m) 
  
  
Figure 9. (P-Band DTM - Bare Lidar) RMSE as a function of 
tree height and for three slope categories («10 degrees, (10 — 
20) degrees, and >20degrees). Tree height classes are 
underestimated (see text) and show intervals (0-5), (5-15), (15- 
25), (25-35) and >35 meters. 
5. DISCUSSION AND CONCLUSIONS 
This presentation has focussed on what the author believes are 
two of the more important ‘events’ that have occurred in the 
past few years, at least as seen from the perspective of 
commercial airborne IFSAR and its growth and contribution to 
mapping. 
The first event was the demonstration of a mapping program on 
a national scale - NextMap Britain - with the capability to 
846 
create DEMs with meter to sub-meter accuracy, posted at 5 
meter intervals. The validation exercises described, one of 
which is perhaps the most extensive to be conducted by the 
mapping industry, would suggest that the ability of airborne 
IFSAR to contribute to a mainstream mapping activity has been 
well and satisfactorily demonstrated. Moreover, the economic 
model described is such that it makes DEM data of mapping 
quality, available to organizations and individuals at prices that 
should promote its use to a greater extent than previously seen. 
This in turn should further the growth of applications based 
upon three-dimensional input. While we have in this paper 
emphasized IFSAR-derived DEMs it is our belief that they are 
complementary to the other technologies both space-borne and 
airborne. The expectation is that we will see increased merging 
of airborne IFSAR with other data sources in order to optimize 
the solutions that users require. 
The second event, is the demonstration of bare-earth DEMs 
beneath significant closed forest canopy derived from fully- 
polarized P-Band IFSAR. Together with X-Band as a proxy for 
tree height, this appears to offer the possibility of creating 
biomass maps and forest fuel mapping implementation (see 
Andersen, et. al. (2004)). To date there have not been many 
examples of long wavelength (L-Band or P-Band) IFSAR bare- 
earth DEMs beneath canopy with well- ground-truthed ancillary 
information. However it is expected that there will be more in 
the near future from both commercial and research 
organizations. There are a number of research issues and 
operational implantations to be addressed that were not 
discussed in this paper. Indeed the status is a long way from 
that demonstrated with X-Band IFSAR in non-forested regions. 
However the potential appears to warrant increased activity in 
this area with consequent rewards for the effort. 
ACKNOWLEDGEMENTS 
The author would like to acknowledge his colleagues at 
Intermap both in Engineering and Operations whose 
contributions were decisive for the success of the two projects 
described in this paper. 
REFERENCES 
Andersen, H-E, R. McGaughey, S. Reutebuch, and B. Mercer. 
2004. Estimation of forest inventory parameters using 
interferometric radar. First International Digital Forestry 
Workshop, Beijing, China. June 14-18. 2004. (to appear) 
Andersen H-E, RJ McGaughey, W. Carson, S. E. Reutebuch, 
B. Mercer, J. Allan, 2003. A Comparison of Forest Canopy 
Models Derived from Lidar and InSAR Data in a Pacific 
Northwest Conifer Forest. Proceedings of the ISPRS WG [11/3 
Workshop on 3-D reconstruction from airborne laserscanner 
and InSAR data, Dresden, Germany 
Cloude, S.R., K.P. Papathanassiou, 1998. Polarimetric SAR 
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5. pp. 1551-1565 
Duncan, A., B. Kerridge, J. Michael, A. Strachan, 2004. The 
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