In: Wagner W., Szekely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
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as the most valuable input for sophisticated scientific analysis
including deriving target physical properties (Chauve et al.,
2009a). It has been demonstrated that full waveform data
provide a significantly more complete and accurate assessment
of the surface, the canopy and potential obstruction detection
than the discrete return system (Magruder et al., 2010).
Moreover, full waveform lidar data capture gives the user much
more flexibility and control in data processing and
interpretation steps (Chauve et al., 2009b). However, dealing
with full waveform datasets takes lidar data management to a
drastically higher level of complexity compared to conventional
3D point cloud data. First, the volume of full waveform data is
overwhelming: about 140 GB for 1.6 hours of data acquisition
time at a 50-kHz pulse repetition frequency (Chauve et al.,
2009b). This can be compared to 12 GB of discrete-return data
with four full records (four ranges, four intensities) for the same
acquisition time and pulse frequency (Optech). Moreover, there
are neither commercial nor open-source toolkits to handle full-
waveform lidar data, but only custom-made solutions typically
designed for specific sensors (Bretar et al., 2008). Therefore,
managing full-waveform lidar data is a very challenging and
expensive task. This limits the commercial use of full
waveform lidar data, confining it mainly to research
institutions.
This paper presents a revolutionary change in the discrete
return airborne lidar technology. It will show that the new, most
advanced airborne lidar system—ALTM Orion—manufactured
by Optech Incorporated, is capable of mapping targets with
complex vertical structure with much higher resolution than has
ever been available before in any discrete return airborne lidar.
A simplified waveform analysis of high-resolution discrete
return data collected over low and medium canopy vegetation
will be presented and discussed in the context of methodology
typically used for full waveform data analysis. It will show that
the new-generation discrete return airborne lidar technology
can provide quality data and some characteristics approaching
that of full waveform data.
2. EVOLUTION OF DISCRETE RETURN AIRBORNE
LIDAR TECHNOLOGY
Initial commercial airborne lidar systems, such as Optech’s
ALTM 1020, 1210 and 1225 models manufactured between
1993 and 1998, had the ability to capture only two returns (first
and last) for each emitted laser pulse. This feature, though
seemingly modest compared to the capabilities of contemporary
advanced airborne lidar systems, already provided enriched
information for sophisticated analysis of both returns for
potential applications such as feature extraction in forest
(Hopkinson et al., 2004; Roberts et al., 2005) or urban areas
(Alharthy and Bethel, 2002). With further evolution of lidar
technology, more advanced ALTM models capable of capturing
four range and four intensity returns became commercially
available, and for the last decade the maximum number of
multiple returns per emitted laser pulse has been stabilized at
this limit.
However, as mentioned, not only the number of multiple
returns is important for the proper mapping of targets with a
complex vertical structure, but also the minimal discrimination
distance between two consecutive returns. The vertical
discrimination distance, that is, minimum distance (time)
separation between consecutive pulse returns, is solely
determined by the lidar system hardware design, and along with
range precision it would determine the type, quality and
accuracy of the consequent data analysis based on discrete
return data. In most commercial discrete return lidar systems
the minimal pulse discrimination distance is close to 2-3.5 m
(Optech ALTM 3100 and Gemini, Leica's ALS series). This
means that targets separated by any distance less than this
minimum cannot be resolved by consecutive multiple returns.
Until recently the numbers characterizing minimal target
separation distances had not been typically specified in the brief
data sheets of most commercial lidar systems, but could be
found in more detailed specification documents, or provided to
users upon request. This situation created some
misunderstanding in the lidar community as users expect to
detect four discrete returns from objects a few meters high
objects without considering the minimum vertical
discrimination distance. The lack of knowledge of this
parameter may also lead to misinterpretation of multiple return
data and even gross systematic errors due to wrong
interpolation. Since the minimum target separation distance
seems to be one of the best performance parameters to
characterize the ability of an airborne lidar system to map
complex vertical targets, it is very important for users to have
this knowledge.
Figures 1-2 present typical examples of multiple return data for
the ALTM 3100 and Gemini systems. In both cases the laser
beam penetrated through 16-20 m of vegetation, and the last
return with strong intensity clearly indicates the signal reflected
from the ground.
Figure 1. ALTM 3100: An example of a four-return record
for one emitted laser pulse with a minimum pulse separation
distance of 2.14 m.
Figure 2. ALTM Gemini: An example of a four-return record
for one emitted laser pulse with a minimum pulse separation
distance of 1.45 m.
Although these two examples represent leading-edge discrete
return airborne lidar technology, it is clear that full waveform
