Abstract
We refined our Shape from Shading (SfS) algorithm, which has previously been used to create digital terrain models (DTMs) of the Lunar and Martian surfaces, to generate high-resolution DTMs of Mercury from MESSENGER imagery. To adapt the reconstruction procedure to the specific conditions of Mercury and the available imagery, we introduced two methodic innovations. First, we extended the SfS algorithm to enable the 3D-reconstruction from image mosaics. Because most mosaic tiles were acquired at different times and under various illumination conditions, the brightness of adjacent tiles may vary. Brightness variations that are not fully captured by the reflectance model may yield discontinuities at tile borders. We found that the relaxation of the constraint for a continuous albedo map improves the topographic results of an extensive region removing discontinuities at tile borders. The second innovation enables the generation of accurate DTMs from images with substantial albedo variations, such as hollows. We employed an iterative procedure that initializes the SfS algorithm with the albedo map that was obtained by the previous iteration step. This approach converges and yields a reasonable albedo map and topography. With these approaches, we generated DTMs of several science targets such as the Rachmaninoff basin, Praxiteles crater, fault lines, and several hollows. To evaluate the results, we compared our DTMs with stereo DTMs and laser altimeter data. In contrast to coarse laser altimetry tracks and stereo algorithms, which tend to be affected by interpolation artifacts, SfS can generate DTMs almost at image resolution. The root mean squared errors (RMSE) at our target sites are below the size of the horizontal image resolution. For some targets, we could achieve an effective resolution of less than 10 m/pixel, which is the best resolution of Mercury to date. We critically discuss the limitations of the evaluation methodology.
Highlights
Mercury has received comparatively little attention among the terrestrial planets, and many scientific questions remain unanswered
At the time of writing, the Mercury Planetary Orbiter (MPO) and Mercury Magnetospheric Orbiter (MMO) of the BepiColombo mission are on their way to Mercury
We found that the elevation root mean squared errors (RMSE) of the reconstructed Praxiteles crater and the ghost crater lies in the range of 20.05 m to 120.00 m, and the RMSE of the derivative along the profile is in the range of 0.025–0.062
Summary
Mercury has received comparatively little attention among the terrestrial planets, and many scientific questions remain unanswered. The Mariner 10 probe of NASA (National Aeronautics and Space Administration) completed three flybys in 1974 and 1975 [1] but imaged only one side of the planet. The first orbiter was NASA’s MESSENGER (MErcury Surface, Space ENvironment, GEochemistry and Ranging), which entered the orbit of Mercury in 2011 and remained there until the end of April 2015 [2]. MESSENGER revolutionized and expanded the understanding of Mercury, which is elaborated in Solomon et al [3], eventually drawing the interest of the community to the innermost planet. BepiColombo is conducted jointly by the European Space Agency (ESA) and Japan Aerospace Exploration Agency (JAXA) and will enter orbit in 2025 to improve, extend, and complement the findings of MESSENGER [4]
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