International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B4, 2012 
XXXIX-B4, 2012 XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
e NAC images are sampled at 12 bits and companded (e.g. 3. METHODOLOGY 
LROC NAC TE AC E. bits. Each camera has a field of view of 2.869, 
which are mounted to overlap by approximately 135 pixels in To produce DEMs of key regions of interest (see workflow in 
the cross-track direction and are offset from each other by ~185 Figure 4), Integrated Software for Image and Spectrometers 
pixels in the down-track direction (Robinson et al. 2010). (ISIS; http:// isis.astrogeology.usgs.gov/index.html; Anderson, et 
conter ‘and tlic al., 2004) routines ingest the images, perform a radiometric 
Stereo images are collected by acquiring images on two correction, and export the image data in SOCET SET format. 
different orbits so that the convergence angle is between 10? The NAC files imported into SOCET SET are radiometrically 
LZ 85287 and 45°. The overlap between the two NAC-L and NAC-R corrected images and contain a list of keywords of relevant 
5m images provides three or four stereo models from which to parameters regarding the spacecraft position and pointing. 
: : collect elevation data. The number of models depends on the : 
- 86001 ~(mrosick, orientation of the images and how they intersect one another. ~~ SOCET SET includes a push broom sensor model that has been 
The amount of overlap and the actual footprint are affected by adapted to handle many spacecraft Cameras (including LROC 
the topography and acquisition parameters such as center NAC) that is used to relate the Image space to ground 
latitude, center longitude, and slew angle. coordinates. A bundle adjustment is performed on the images to 
correct for offsets in camera pointing using a multi-sensor 
g, Processing 22 LOLA triangulation (MST) algorithm. MST is used to update camera 
pointing, improve registration between areas of stereo coverage, 
and ground truth using tie-points, sensor position, and camera 
pointing. Tie points relate a point in the overlapping area of two 
or more images, while ground points register a point or 
identifiable object in the image to a point on the ground. 
Selected parameters, such as the position, velocity, and pointing 
angles of the cameras are adjusted so that the root mean square 
(RMS) errors for all the tie point measurements are minimized. 
Stereo pairs can be mosaicked together by placing tie points in 
areas of stereo coverage (Figure 3). Mosaicking stereo pairs 
tends to increase the overall RMS error when applying a bundle 
adjustment to the sets of images, revealing the presence of 
unmodeled systematic errors. For example, in images with 
minimal change in slew angle during image acquisition, the 
offset between image sets is less than 1 meter. When spacecraft 
maneuvers do not maintain a constant slew angle during image 
acquisition (which can be quite irregular and may not be well 
modeled by the adjusted parameters), the offsets can vary 
between 3 m to 15 m. 
observations with the 
iis work describes the 
1 of USGS integrated 
tate University (ASU). 
> than 130 stereo pairs 
sampling is typically 2 
v of the lunar surface 
addition to exploration 
nposition and geologic 
  
ES 
  
  
Figure 2. LOLA spot pattern (Smith et al. 2010). 
Altimetry obtained from the Lunar Orbiter Laser Altimeter 
(LOLA) is used to increase the absolute accuracy of NAC 
DEMs. LOLA was designed to measure the shape of the Moon 
by precisely measuring the range from the spacecraft to the 
surface, and incorporating precision orbit determination of LRO 
by referencing surface ranges to the Moon's center of mass. Its 
primary objective is to produce a global geodetic grid for the 
Moon to which all other observations can be precisely 
referenced (Smith et al. 2010). LOLA is a pulse detection 
time-of-flight altimeter that incorporates a five-spot pattern to 
measure the precise distance to the surface at 5 spots 
simultaneously, thus providing 5 profiles for each orbit. LOLA 
; iy fires at a fixed, 28 Hz rate, so that for a nominal 1600 m/s 
vo image acquisition ground track velocity, there is one shot approximately every 57 
meters. At a nominal 50 km altitude, each spot within the five- 
  
  
  
  
  
  
Spot pattern has a diameter of 5 meters while each detector field Figure 3. Color shaded relief terrain model derived from a NAC 
cameras built using the of view has diameter of 20 meters. The spots are 25 meters DEM mosaic of 13 stereo pairs of Lichtenberg Crater. The 
rray is a 5064 element apart and form a cross pattern canted by 26° counter-clockwise enlargements display color shaded terrain, slope map, and 
icron pixels. The two to provide five adjacent profiles (Figure 2) (Smith et al. 2010, orthophoto derived from the DEM mosaic. 
t (NAC-L) and NAC- Zuber etal. 2010). The LOLA instrument boresight is aligned ; 
| on the spacecraft such With the LROC NAC cameras to enable altimetry collection in To improve absolute accuracy between the images, LOLA 
e spacecraft’s X-axis. the overlap region between NAC-L and NAC-R. By using altimetric profiles are used to define the geodetic reference 
0.5 meter pixel scale Earth-based laser ranging tracking and crossover analysis the frame for the DEMs. The images are shifted in relation to their 
swath cross-track, for a accuracy of the LOLA dataset is improved. original latitude, longitude, scale, elevation, and horizontal and 
tude of 50 km. Each vertical rotation, using a script in MATLAB, in order to better 
allowing for an image fit the LOLA data. 
it the native resolution. 
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