Full text: Proceedings, XXth congress (Part 4)

  
  
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B4. Istanbul 2004 
  
process would be required even if the photometric function 
were precisely known (e.g., even for visible band images 
without "magic airbrush" processing; see section 3 below 
and Kirk et al., 2003b) because the image contains a uniform 
additive offset that affects its constant. This offset comes in 
part from atmospheric haze in the VIS image, which varies 
with time and is not known a priori. Figure 2 shows the 
photoclinometric DEM from the example of Fig. 1, with a 
MOLA DEM of the same area for comparison. The 
photoclinometry adds local details while preserving long- 
wavelength topography such as the height of the 10-km 
wide mesa at the bottom. The detailed DEM can be used to 
simulate the VIS image with realistic photometric function 
pv but no albedo variations. Dividing the VIS image (after 
subtraction of a constant haze value) by the simulation 
yields a map of albedo variations that can reveal subtle 
features, e.g., the dark slopes on the sides of the mesa in Fig. 
2d. The DEM can also be used to map absolute and 
directional slopes. 
We extended the analysis shown in Figs. 1-2 to neighboring 
THEMIS VIS/IR triplets in order to produce topographic, 
slope, and albedo maps of essentially the entire MER-A 
(Spirit) landing ellipse, and also the MER-B (Opportunity) 
ellipse. These landing sites are among the first areas on Mars 
for which nearly complete VIS coverage is available, but 
current mission plans will lead to the eventual collection of 
global IR imagery and VIS images of about half the planet. 
MOLA-resolved features that could be used to calibrate 
photoclinometry were present in only a few of the images, so 
the remainder were calibrated to have similar slopes on 
small-scale features. As it happened, Spirit landed within 
the images shown here, about 2 km west of the triangle of 
hills seen at the top center. Our THEMIS maps were useful in 
the early days of the mission for locating the landing point, 
to ~100-m accuracy by tracing sightlines to features visible 
from the lander. Hypothetical lander locations were also 
tested by using the DEM to simulate the appearance of the 
visible horizon. The high resolution of our maps (compared, 
e.g., to MOLA) was critical for this application. 
3. MARS EXPRESS HRSC 
3.1 Source Data 
In early January 2004, the ESA Mars Express mission started 
Its science phase in orbit around Mars. Imaging and 
mapping the Martian surface by the High Resolution Stereo 
Camera (HRSC) is one of the main goals of Mars Express. 
The HRSC experiment (Albertz et al., 1992; Neukum et al., 
2004) is a pushbroom scanning instrument with 9 CCD line 
detectors mounted in parallel on the focal plane. Its unique 
feature is the ability to nearly simultaneously obtain 
imaging data of a specific site at high resolution, with 
along-track triple stereo, with four colors, and at five 
different phase angles, thus avoiding any time-dependent 
variations of the observation conditions. An additional 
Super-Resolution Channel (HRSC-SRC, a framing device) is 
yielding nested-in images in the meter-range thus serving as 
the sharpening eye for detailed photogeologic studies. The 
spatial resolution from the nominal periapsis altitude of 250 
km is 10 m/pixel for the HRSC proper and 2.3 m/pixel for 
the SRC. The SRC images are normally acquired vertically, 
but a subset are oblique because of spacecraft maneuvers to 
fill gaps in image coverage. 
3.2 Stereo Mapping Methodology 
Our approach to processing HRSC data is largely 
independent of those used by other members of the camera 
team, which are described in several papers in this volume 
(Hauber et al., 2004; Oberst et al., 2004; Ebner et al., 2004; 
Heipke et al., 2004; Dorrer et al., 2004). We start with images 
in VICAR format that have been radiometrically calibrated at 
the German Aerospace Center (DLR) in Berlin. These images 
are ingested into the USGS in-house digital cartographic 
836 
software ISIS (Eliason, 1997; Gaddis et al., 1997; Torson and 
Becker, 1997; see also http://isis.astrogeology.usgs.gov). 
[In particular, the supporting cartographic information in the 
VICAR labels is converted into its ISIS equivalents. Be- 
cause ISIS, unlike VICAR, does not currently accommodate 
changing line exposure times within a scanner image, the 
images are if necessary broken into multiple files that cach 
have a constant exposure time. 
From this point onward, our approach to topographic 
mapping with the HRSC images is similar to those we have 
used for a wide range of planetary datasets (Kirk et al., 
2000a), and, in particular, for the Mars Global Surveyor 
MOC images as described in detail in a recent paper (Kirk et 
al., 2003a). We usec ISIS for mission-specific steps (data 
ingestion and, for most instruments, calibration, though for 
HRSC the latter has been performed in VICAR), as well as 
"2D" processing such as map-projection and image mosaick- 
ing. The ISIS projection capability now includes ortho- 
rectification, and detailed photometric models of the surface 
and atmosphere (Kirk et al., 2000b, 2001) can be used to 
correct the images for variations in illumination and atmo- 
spheric haze before mosaicking. Two dimensional photo- 
clinometry is also implemented in ISIS (Kirk et al., 2003b). 
Our commercial digital photogrammetric workstation 
running BAE Systems SOCET SET ® software (Miller and 
Walker, 1993; 1995) is used for "3D" processing steps such 
as control of the images and automatic extraction and 
manual editing of DEMs. SOCET SET includes a pushbroom 
scanner sensor model that is physically realistic but 
"generic" enough to describe the individual HRSC scanner 
lines, as well as most images from the Mars Global Surveyor 
Mars Orbiter Camera (MOC). SRC images can be imported 
and used with the frame sensor model. We have written 
software to import these and other types of images from ISIS 
into SOCET SET and to translate the orientation data in ISIS 
into the necessary format. In this process, each HRSC 
detector array must be treated as separate single-line camera, 
oriented at an appropriate pitch angle to model the true 
geometry of the instrument. Because SOCET SET is unaware 
that the images from the different HRSC lines are collected at 
the same time, the intrinsic robustness of the multiline 
stereo system is unfortunately lost. This is a relatively 
minor disadvantage, given the availability of the MOLA 
global topographic dataset, which provides control with an 
accuracy on the order of 10 m vertically and 100 m 
horizontally (Smith et al., 2001; Neumann et al., 2001). The 
disadvantage is more than made up for in practice by the 
ability of SOCET SET to perform bundle adjustments that 
include images from sensors of different types (e.g., SRC and 
MOC), and to produce DEMs from stereopairs of mixed type. 
Nevertheless, we plan to extend the bundle-adjustment 
software being developed for the THEMIS IR scanner 
(Archinal et al., 2004) to model the HRSC with proper 
accounting for the constraints between image lines. This 
software may also eventually be extended to model the high- 
frequency pointing variations ("jitter") that affect many 
MOC narrow-angle (NA) images. Because the SOCET SET 
adjustment software we are now using includes only 
smoothly varying pointing corrections, we must use ad hoc 
processing by spatial filtering to remove the jitter-related 
artifacts from MOC DEMs. 
The MOC NA images are well suited in terms of resolution 
for stereomapping in conjunction with SRC images. The 
fundamental resolution of the camera is 1.4 m/pixel, but 
images are most often obtained by pixel summation at 
resolutions close to 3 or 6 m (Malin and Edgett, 2001). 
More than 50,000 NA images have been obtained so far (see 
http://www.msss.com/mars images/index.html and http:// 
ida.wr.usgs.gov/), and we have been able to locate vertical or 
near-vertical images that overlap several of the handful of 
oblique SRC image sets that have been obtained while the 
Mars Express spacecraft is rolled off of its normal vertical 
orientation. A larger number of pairs combining off-vertical 
MOC images with the hundreds of vertical SRC images are 
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