Your search keyword '"Howington-Kraus, Elpitha"' showing total 2 results

1. Comparison of USGS and DLR topographic models of Comet Borrelly and photometric applications

Author

Kirk, Randolph L., Howington-Kraus, Elpitha, Soderblom, Laurence A., Giese, Bernd, and Oberst, Jurgen

Subjects

Comets, Astronomy, Earth sciences

Abstract

Stereo analysis of images obtained during the 2001 flyby of Comet Borrelly by NASA's Deep Space 1 (DS1) probe allows us to quantify the shape and photometric behavior of the nucleus. The shape is complex, with planar facets corresponding to the dark, mottled regions of the surface whereas the bright, smooth regions are convexly curved. The photometric as well as textural differences between these regions can be explained in terms of topography (roughness) at and below the image resolution, without invoking significant variations in single-particle properties; the material on Borrelly's surface could be quite uniform. A statistical comparison of the digital elevation models (DEMs) produced from the three highest-resolution images independently at the USGS and DLR shows that their difference standard deviation is 120 m, consistent with a matching error of 0.20 pixel (similar to reported matching accuracies for many other stereo datasets). The DEMs also show some systematic differences attributable to manual versus automatic matching. Disk-resolved photometric modeling of the nucleus using the DEM shows that bright, smooth terrains on Borrelly are similar in roughness (Hapke roughness [theta] = 20[degrees]) to C-type asteroid Mathilde but slightly brighter and more backscattering (single-scattering albedo w = 0.056, Henyey-Greeustein phase parameter g = -0.32). The dark, mottled terrain is photometrically consistent with the same particles but with roughnesses as large as 60[degrees]. Intrinsically darker material is inconsistent with the phase behavior of these regions. Many local radiance variations are clearly related to topography, and others are consistent with a topographic explanation; one need not invoke albedo variations greater than a few tens of percent to explain the appearance of Borrelly. Published by Elsevier Inc. Keywords: Borrelly; Small bodies; Topography: Photogrammetry; Photometry

Published

2004

2. Topography and geomorphology of the Huygens landing site on Titan

Author

Soderblom, Laurence A., Tomasko, Martin G., Archinal, Brent A., Becker, Tammy L., Bushroe, Michael W., Cook, Debbie A., Doose, Lyn R., Galuszka, Donna M., Hare, Trent M., Howington-Kraus, Elpitha, Karkoschka, Erich, Kirk, Randolph L., Lunine, Jonathan I., McFarlane, Elisabeth A., Redding, Bonnie L., Rizk, Bashar, Rosiek, Mark R., See, Charles, and Smith, Peter H.

Subjects

*GENEALOGY, *ALIPHATIC compounds, *CHLOROBUTANE, *DIAZOALKANES, *BIOMASS chemicals

Abstract

Abstract: The Descent Imager/Spectral Radiometer (DISR) aboard the Huygens Probe took several hundred visible-light images with its three cameras on approach to the surface of Titan. Several sets of stereo image pairs were collected during the descent. The digital terrain models constructed from those images show rugged topography, in places approaching the angle of repose, adjacent to flatter darker plains. Brighter regions north of the landing site display two styles of drainage patterns: (1) bright highlands with rough topography and deeply incised branching dendritic drainage networks (up to fourth order) with dark-floored valleys that are suggestive of erosion by methane rainfall and (2) short, stubby low-order drainages that follow linear fault patterns forming canyon-like features suggestive of methane spring-sapping. The topographic data show that the bright highland terrains are extremely rugged; slopes of order of 30° appear common. These systems drain into adjacent relatively flat, dark lowland terrains. A stereo model for part of the dark plains region to the east of the landing site suggests surface scour across this plain flowing from west to east leaving ∼100-m-high bright ridges. Tectonic patterns are evident in (1) controlling the rectilinear, low-order, stubby drainages and (2) the “coastline” at the highland–lowland boundary with numerous straight and angular margins. In addition to flow from the highlands drainages, the lowland area shows evidence for more prolific flow parallel to the highland–lowland boundary leaving bright outliers resembling terrestrial sandbars. This implies major west to east floods across the plains where the probe landed with flow parallel to the highland–lowland boundary; the primary source of these flows is evidently not the dendritic channels in the bright highlands to the north. [Copyright &y& Elsevier]

Published

2007