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(AHGF, http;//www.bom.gov.au/water/geofabric/index.shtml,
commonly known as the ‘Geofabric’), an authoritative and rich
representation of Australia’s hydrological features.
The tree height offset map could be used as the basis of a high
resolution map of forest height and biomass, provided suitably
robust relationships can be found between height offset and
actual tree height. Note that the tree height offset derived from
the SRTM data is not a measure of true tree height, primarily
because the SRTM radar signal scatters from the woody
structure within the canopy rather than the upper margin of the
canopy (Kellndorfer et al., 2004). Preliminary study of the
estimated offsets suggests the estimated heights are a smaller
fraction of true height in trees with a conical shape (typically
conifers) than in trees with a broad canopy (such as most
Australian eucalypts), presumably due to greater penetration of
the radar signal into the former canopy type.
3.2 Prospects for processing of the global SRTM DSM
The processing method for estimating and removing tree height
offsets in the SRTM DSM could in principle be applied to the
entire SRTM dataset. The most significant obstacle to
attempting this is the need for a consistent global land cover
map compatible with the SRTM data in both resolution and
acquisition date. Global cover maps currently exist at
resolutions of about 300 m (GlobCover) and 500 m (MODIS
Land Cover). Finer resolution products from Landsat might also
be possible, and it is also possible that the raw SRTM radar
product would contain useful information for detecting
vegetation cover boundaries.
Independent measures of tree height (suitably modified to
account for SRTM penetration into the canopy) could be
incorporated into the height offset estimation process. This
would be particularly helpful in extensively forested areas
where there are likely to be spatial variations in tree height that
cannot be estimated from patch edges. Either direct
measurements from instruments such as the GLAS laser
altimeter aboard ICESat or indirect measurements based on
multispectral imagery could be used. Some promising progress
in combining those two approaches was reported by Lefsky
(2010) using GLAS and MODIS data to produce a global tree
height map. While this is at a relatively coarse resolution it may
provide sufficient information to support improved offset
estimates in extensive forest areas; further development of the
methods could also provide improved information. Combining
the various data sources under a model-data fusion approach
may also be possible, yielding a tree map, tree heights and bare-
earth DEM from a single process.
3.3 Application to other DSM types
While some of the aspects of the algorithm are specific to
SRTM, notably the matching of response to patch edges, much
of the method is in principle directly applicable to any DSM
that responds predictably to vegetation cover. A bare-carth
DEM is usually produced from a DSM by manually driven
editing and hence tends to be quite expensive. A fully
automated method, even if it is not as accurate as a manually
driven method, is attractive where very large areas of DSM need
to be processed, as with global or continental DSMs like
SRTM.
Two obvious candidates for processing using the method
presented here are the ASTER GDEM and TANDEM-X
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B4, 2012
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia
products (although the ASTER GDEM response to trees does
not seem as consistent as the SRTM so may be less amenable to
treatment). Both are essentially DSMs and would benefit from
removal of offsets due to tree cover.
4. CONCLUSIONS
Removing artefacts from Digital Surface Models is a
prerequisite for deriving high quality bare-earth Digital
Elevation Models. The methods described here provide that
capability, drawing on an appropriately fine resolution
vegetation (tree) map as supporting data. The resulting bare-
earth DEM for Australia is now being used for a variety of
ecological, hydrological and geomorphological applications.
The methods described here could be applied to the entire
SRTM near-global DSM, provided a suitable tree cover map
can be compiled. This would be a valuable step in realising the
full value of this high resolution, high quality product and
would complement other efforts such as those by CGIAR to
provide a void-filled version of the SRTM DSM.
The method may also be suitable for removing offsets due to
tree cover in other remotely sensed DSMs such as ASTER
GDEM and TANDEM-X. Some adaptation to the different
characteristics of these DSMs would be required.
5. REFERENCES
Dowling, T.I, A.M. Read, M.F. Hutchinson, and J.C. Gallant,
in prep. Drainage enforcement of the 1 second SRTM DEM for
Australia.
Farr, T.G., P.A. Rosen, E. Caro, R. Crippen et al. (2007), The
shuttle radar topographic mission, Reviews of Geophysics, 45,
RG2004.
Gallant, J.C., 2011. Adaptive smoothing for noisy DEMs. In:
Geomorphometry 2011, International Society for
Geomorphometry. Redlands, California.
http://www.geomorphometry.org/Gallant2011.
Gallant, J.C., AM. Read, T.I. Dowling, and J.M. Austin, in
prep. Removing vegetation offsets from the 1 second SRTM
DEM for Australia.
Grohman, G., G. Kroenung, and J. Strebeck, 2006. Filling
SRTM voids: The delta surface fill method. Photogrammetric
Engineering and Remote Sensing, 72(3), pp. 213-216.
Hutchinson, M.F., T. Xu and J.A. Stein, 2011. Recent progress
in the ANUDEM elevation gridding procedure. In:
Geomorphometry | 2011, International Society for
Geomorphometry. Redlands, California.
http://geomorphometry.org/HutchinsonXu201 1.
Kellndorfer, J., W. Walker, L. Pierce, C. Dobson, J.A. Fites, C.
Hunsaker, J. Vona, and M. Clutter, 2004. Vegetation height
estimation from Shuttle Radar Topography Mission and
National Elevation Datasets. Remote Sensing of Environment,
93(3), pp. 339-358.
Kóthe, R., and M. Bock, 2009. Preprocessing of digital
elevation models - derived from laser scanning and radar
interferometry - for terrain analysis in geosciences. In:
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http://www.geomorphometry.org/KoetheBock2009.
