8/8/2023 0 Comments Lunar orbiter 1![]() Zuber, Outstanding questions on the internal structure and thermal evolution of the Moon and future prospects from the GRAIL mission. Zuber, The shape and internal structure of the Moon from the Clementine mission. Zuber, The Mars Observer Laser Altimeter investigation. ![]() ![]() Wieczorek, Gravity and topography of the terrestrial planets. Geological Survey, Color-coded topography and shaded relief map of the lunar near side and far side hemispheres. Sun et al., Radiometry measurements of Mars at 1064 nm using the Mars Orbiter Laser Altimeter. Spudis, Ancient multiring basins on the Moon revealed by Clementine laser altimetry. Soderblom, A model for small-impact erosion applied to the lunar surface. Smith, Mars Orbiter Laser Altimeter: Experiment summary after the first year of global mapping of Mars. Smith, The global topography of Mars and implications for surface evolution. Smith, Topography of the Moon from the Clementine LIDAR. Schutz, Laser altimetry and LIDAR from ICESat/GLAS. Schultz, Igneous dikes on Mars revealed by Mars Orbiter Laser Altimeter topography. Rowlands, The use of laser altimetry in the orbit and attitude determination of Mars Global Surveyor. Robinson et al., The Lunar Reconnaissance Orbiter Camera (LROC). NASA/Goddard Space Flight Center, Greenbelt, MD, 2008 Ramos-Izquierdo et al., The Lunar Orbiter Laser Altimeter (LOLA) optical subsystem, 2009 Quaide, Rilles, ridges and domes-Clues to maria history. Qian, Topography of the Moon from the Chang’e Laser Altimetry Data, 2008 Raytheon ITTS Contractor Report, Lanham, MD, 2001 Pavlis et al., GEODYN Operations Manuals. Nozette, The Clementine mission to the Moon: Scientific overview. Neumann, The crossover analysis of MOLA altimetric data. Melosh, Impact Cratering: A Geologic Process (Oxford University Press, New York, 1989). Konopliv, Recent gravity models as a result of the Lunar Prospector mission. Kamalakar, Lunar ranging instrument for Chandrayaan-1. Hartmann, Moon: Origin and evolution of multi-ring basins. Matsumoto, Lunar degree 2 potential Love number determination from satellite tracking data. Gardner, Target signatures for laser altimeters: an analysis. Williams, Planetary Ephemeris DE421 for Phoenix Navigation (Jet Propulsion Laboratory, Pasadena, 2008) Dickey, Lunar laser ranging: A continuing legacy of the Apollo program. Cook, Lunar polar topography derived from Clementine stereoimages. Chin, Lunar Reconnaissance Orbiter overview: The instrument suite and mission. Cavanaugh, The Mercury Laser Altimeter instrument for the MESSENGER mission. Araki, Lunar global shape and polar topography derived from Kaguya-LALT laser altimetry. Abshire, Geoscience Laser Altimeter System (GLAS) in the ICESat mission: On-orbit measurement performance. The orbiter will also identify potential landing sites for future lunar missions.ĭisclaimer: This story has not been edited by the Sakshi Post team and is auto-generated from syndicated feed.J.B. It is assigned to measure the terrain, magnetic strengths, gamma rays and other traits of the lunar surface using six onboard instruments until the end of this year. The science ministry said people can check the real-time location of Danuri on the lunar orbit, along with its photos and collected data, on the orbiter's website.ĭanuri entered the selenocentric orbit on December 27 after 145 days of travelling from Earth and started its operation on February 4 about a month after test runs. On top of that, Danuri has sent separate photos taken with its wide-angle polarimetric camera, PolCam for short, designed to study the moon's surface composition and its volcanic deposits through measuring the degree of polarisation. They are the first photos of the moon's far side that South Korea has taken, reports Yonhap news agency. Seoul, April 12 (IANS) South Korea's unmanned space vehicle Danuri has sent photos of the moon's far side during its mission to collect selenographic data, the science ministry said on Wednesday.ĭanuri, which is rotating around the moon 100 kms above the surface, took pictures of the Tsiolkovskiy crater on March 22 and the Vallis Schrodinger and Szilard M craters each on March 24 with its high-definition cameras, according to the Ministry of Science and ICT and the Korea Aerospace Research Institute (KARI).
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |