{"collections":[{"abstract":"This page introduces the Kaguya Multiband Imager derived spectral and derived mineral maps by the Japan Aerospace Exploration Agency (JAXA) and the University of Hawaii. The mosaics were created from topographically-corrected MI","geoform":["Collection"],"name":"lunar-kaguya-multiband-imager-mosaics","onlink":"https://astrogeology.usgs.gov/search/map/lunar-kaguya-multiband-imager-mosaics","pubdate":"2015-01-01","thumb":"https://astrogeology.usgs.gov/ckan/dataset/a53c9dbf-e03a-4d7a-8641-fc7af97a75c2/resource/a7e1a610-f8ef-4080-99e0-1b637d6c269f/download/moon-selene-kaguya-mi-thumb.jpg","title":"Lunar Kaguya Multiband Imager Mosaics"},{"abstract":"<span class=\"intro\">The following products were the first step of cartography planning</span> in support of the Cassini-Huygens mission to the Saturian System. Five of Saturans moons are linked below in a standard cartographic","geoform":["Collection"],"name":"saturn-voyager-airbrush-global-products","onlink":"https://astrogeology.usgs.gov/search/map/saturn-voyager-airbrush-global-products","pubdate":"2023-10-05","thumb":"https://astrogeology.usgs.gov/ckan/dataset/0872355e-41d2-48be-a3f3-474c571911e0/resource/fe0f7b0d-3a95-40f3-ad90-103ee20b2342/download/rhea-voyager-thumb.png","title":"Saturn Voyager Airbrush Global Products"},{"abstract":"<span class=\"intro\">Distributed here are control network data</span> for solar system bodies (planets, moons, and asteroids) other than the Earth. Each control network is essentially a set of photogrammetric or radargrammetric solution (input","geoform":["Collection"],"name":"control-networks","onlink":"https://astrogeology.usgs.gov/search/map/control-networks","pubdate":null,"thumb":"https://astrogeology.usgs.gov/ckan/dataset/c14e7072-decf-4997-925f-c7f305d2dd44/resource/f41d1d4e-daa4-484b-b6e2-439a93c3af58/download/control-networks-thumb.jpeg","title":"Control Networks"},{"abstract":"<span class=\"intro\">This gallery features several digitized photographs</span> from Apollo Mission explorations of the lunar surface. Anaglyph or 3D images require red-blue or red-green 3D glasses. The imagery and maps were prepared as","geoform":["Collection"],"name":"moon-apollo-anaglyph-3d-images","onlink":"https://astrogeology.usgs.gov/search/map/moon-apollo-anaglyph-3d-images","pubdate":"2023-10-20","thumb":"https://astrogeology.usgs.gov/ckan/dataset/8cd5663b-8ad1-44d4-9ef9-bac956de07a4/resource/2adf2528-8613-4545-a184-c8b31e08669f/download/apollo_stereo-thumb.jpg","title":"Moon Apollo Anaglyph 3D Images"},{"abstract":"<span class=\"intro\">This page features several maps showing routes</span> the astronauts took during extravehicular activities (EVAs). The imagery and maps were prepared as part of a project by a USGS team under funding","geoform":["Collection"],"name":"moon-apollo-traverse-maps","onlink":"https://astrogeology.usgs.gov/search/map/moon-apollo-traverse-maps","pubdate":"2023-10-16","thumb":"https://astrogeology.usgs.gov/ckan/dataset/b499160d-149f-4a79-8aee-e4a09d50fb80/resource/af3a32f8-eb16-48cc-8fd4-0b0881d440d5/download/apollo14_traverse-thumb.jpg","title":"Moon Apollo Traverse Maps"},{"abstract":"<span class=\"intro\">The USGS Astrogeology Science Center created some of the finest cartographic products</span> of Mars using data from Viking Oribter. Some of these products include global mosaics, north and south polar stereographic","geoform":["Collection"],"name":"mars-viking-global-products","onlink":"https://astrogeology.usgs.gov/search/map/mars-viking-global-products","pubdate":"2023-10-16","thumb":"https://astrogeology.usgs.gov/ckan/dataset/817ca072-b931-49d2-9056-c07e62c4038f/resource/9c90727e-5452-465d-9bb3-9d5a260b4607/download/mars-viking-thumb.jpg","title":"Mars Viking Global Products"},{"abstract":"<span class=\"intro\">The objective of this work is to assemble</span> and cartographically control Thermal Emission Imaging System (THEMIS; Christensen et al. 2004) daytime infrared (IR) and nighttime IR images. In a cartographically controlled","geoform":["Collection"],"name":"mars-themis-controlled-mosaics-and-final-smithed-kernels","onlink":"https://astrogeology.usgs.gov/search/map/mars-themis-controlled-mosaics-and-final-smithed-kernels ","pubdate":"2023-10-13","thumb":"https://astrogeology.usgs.gov/ckan/dataset/f79e28e3-a4f0-4eba-895a-f5ec96da7f99/resource/723b02d2-3e2d-4d18-94e8-999a68b21125/download/mars_tile_map_thumb.jpg","title":"Mars THEMIS Controlled Mosaics and Final Smithed Kernels"},{"abstract":"<span class=\"intro\">New Horizons launched on Jan. 19, 2006</span> as part of NASA\u2019s New Frontiers Program. The spacecraft will help scientists back on Earth study the surface and atmosphere of the dwarf planet","geoform":["Collection"],"name":"new-horizon-global-mosaics","onlink":"https://astrogeology.usgs.gov/search/map/new-horizon-global-mosaics","pubdate":"2023-10-06","thumb":"https://astrogeology.usgs.gov/ckan/dataset/ee77b8eb-73c4-48c8-8c96-8692c9f03149/resource/0e9e8592-ab83-42d5-ad64-78d683f54f34/download/pluto-new-horizon-thumb.jpg","title":"New Horizon Global Mosaics"}],"facets":{"geoform":{"facet":{"3D":4,"Airbrush":5,"Anaglyph":4,"Archive":3,"Collection":18,"Color":2,"Control Network":24,"Data":3,"Digital Elevation Model":55,"Document":18,"Geologic Map":245,"Global Mosaic":117,"Globe":9,"Grey Scale":7,"Image":46,"Landing Site Map":31,"Mineral Map":11,"Nomenclature":272,"Panorama":38,"Polar Map":6,"Poster":5,"Presentation":4,"Raster Data":431,"Regional Mosaic":622,"Remote-sensing Data":129,"Shaded-Relief Map":128,"Tabular Data":4,"Topographic Map":16,"Traverse Map":5,"Vector Data":242},"label":"Geo Format"},"mapprojn":{"facet":{"":18,"Equirectangular":87,"Lambert Conformal":240,"Mercator":214,"Orthographic":3,"Polar Stereographic":64,"Simple Cylindrical":206,"Sinusoidal":5,"Stereographic":2,"Transverse Mercator":222},"label":"Map Projection"},"missikey":{"facet":{"Apollo":55,"Artemis":2,"Cassini-Huygens":26,"Chandrayaan":1,"Clementine":11,"Dawn":9,"Galileo":36,"Kaguya":21,"Lunar Orbiter":4,"Lunar Reconnaissance Orbiter":168,"MESSENGER":26,"Magellan":76,"Mariner":3,"Mariner 9":12,"Mars 2020":7,"Mars Express":8,"Mars Global Surveyor":10,"Mars Odyssey":119,"Mars Reconnaissance Orbiter":58,"NEAR":2,"New Horizons":6,"OSIRIS-REx":3,"Viking":16,"Viking Lander":2,"Viking Orbiter":337,"Voyager":107},"label":"Mission"}},"page":"1","results":[{"abstract":"This new global topographic map of Enceladus represents our best and most accurate shape model and DEM of the surface of this active icy moon of Saturn (Schenk and McKinnon, 2024). It","geoform":["Archive","Control Network","Digital Elevation Model","Global Mosaic","Grey Scale","Raster Data","Topographic Map"],"name":"enceladus-cassini-global-dem-200m-schenk","onlink":"https://astrogeology.usgs.gov/search/map/enceladus-cassini-global-dem-200m-schenk","pubdate":"2024-08-12","thumb":"https://astrogeology.usgs.gov/ckan/dataset/811a9e97-16f8-460d-b3aa-a8125ea3a2a5/resource/5df08488-d2a8-4458-85f3-1e39da7b35a1/download/enceladus_cassini_dem_global_200m_schenk2024_100.jpg","title":"Enceladus Cassini Global DEM 200m Schenk"},{"abstract":"This download consists of 14 Eros global albedo mosaics across 7 filters and 2 map projections (Simple Cylindrical and Sinusoidal). The data is hosted as GeoTiffs with PDS4 and ISIS3 detached labels.","geoform":["Global Mosaic","Image","Raster Data","Remote-sensing Data"],"name":"near_msi_albedo_mosaics","onlink":"https://astrogeology.usgs.gov/search/map/near_msi_albedo_mosaics","pubdate":"2023-06-16","thumb":"https://astrogeology.usgs.gov/ckan/dataset/d5795858-2f78-44f1-b719-e5fe99a5e440/resource/8d9e4b8c-3ac0-4883-aee2-5a77ef4adefe/download/thumb.png","title":"NEAR MSI Albedo Mosaics"},{"abstract":"This digital terrain model (DTM) mosaic over the south polar region of Mars was generated by extracting three-dimensional point clouds from approximately 400 distinct CTX stereo image pairs and interpolating them to","geoform":["Digital Elevation Model","Polar Map","Remote-sensing Data"],"name":"mars_mro_ctx_south_polar_digital_terrain_model_mosaic_50m","onlink":"https://astrogeology.usgs.gov/search/map/mars_mro_ctx_south_polar_digital_terrain_model_mosaic_50m","pubdate":"2020-09-30","thumb":"https://astrogeology.usgs.gov/ckan/dataset/d7a16ff4-3a0a-4734-b8e0-3b6045218824/resource/0e7cabde-5551-4fb7-aea6-25b585462818/download/ctx_abs_align_iau_deltaradius_mosaic_thumb.jpg","title":"Mars MRO CTX South Polar Digital Terrain Model Mosaic 50m"},{"abstract":"The Mars 2020 rover will explore Jezero crater, Mars to investigate an ancient delta for evidence of past microbial life and to better understand the geologic history of the region. The landing","geoform":["Digital Elevation Model","Landing Site Map","Raster Data","Remote-sensing Data","Topographic Map"],"name":"mars_2020_terrain_relative_navigation_hirise_dtm_mosaic","onlink":"https://astrogeology.usgs.gov/search/map/mars_2020_terrain_relative_navigation_hirise_dtm_mosaic","pubdate":"2020-07-24","thumb":"https://astrogeology.usgs.gov/ckan/dataset/381ba037-d8a9-4cea-86be-374e4951afe3/resource/4c21ed76-5e96-4cdb-9014-a373633c615f/download/jez_hirise_soc_006_dtm_molatopography_deltageoid_1m_eqc_latts0_lon0_blend40_100.jpg","title":"Mars 2020 Terrain Relative Navigation HiRISE DTM Mosaic"},{"abstract":"This is a visible image mosaic generated from the Context Camera (CTX) images from the Mars Reconnaissance Orbiter mission. This product is the Lander Visions System (LVS) map that will be onboard","geoform":["Grey Scale","Image","Landing Site Map","Remote-sensing Data"],"name":"mars_2020_terrain_relative_navigation_context_camera_orthorectified_image_mosaic","onlink":"https://astrogeology.usgs.gov/search/map/mars_2020_terrain_relative_navigation_context_camera_orthorectified_image_mosaic","pubdate":"2020-07-24","thumb":"https://astrogeology.usgs.gov/ckan/dataset/bce399c8-ce5a-4653-97dc-6d37ada26528/resource/e6a7d794-8604-4721-b845-2ebe6d012e11/download/jez_ctx_b_soc_008_orthomosaic_6m_eqc_latts0_lon0_100.jpg","title":"Mars 2020 Terrain Relative Navigation Context Camera Orthorectified Image Mosaic"},{"abstract":"The Mars 2020 rover will explore Jezero crater, Mars to investigate an ancient delta for evidence of past microbial life and to better understand the geologic history of the region. The landing","geoform":["Digital Elevation Model","Landing Site Map","Remote-sensing Data","Topographic Map"],"name":"mars_2020_terrain_relative_navigation_ctx_dtm_mosaic","onlink":"https://astrogeology.usgs.gov/search/map/mars_2020_terrain_relative_navigation_ctx_dtm_mosaic","pubdate":"2020-07-24","thumb":"https://astrogeology.usgs.gov/ckan/dataset/2d14f45e-e7d3-41e7-aa50-9a8d080cf3cc/resource/44a56fb7-7755-48c4-89ab-5b5b00fd1643/download/jez_ctx_b_soc_008_dtm_molatopography_deltageoid_20m_eqc_latts0_lon0_100.jpg","title":"Mars 2020 Terrain Relative Navigation CTX DTM Mosaic"},{"abstract":"The Mars 2020 rover will explore Jezero crater, Mars to investigate an ancient delta for evidence of past microbial life and to better understand the geologic history of the region. The landing","geoform":["Grey Scale","Landing Site Map","Raster Data","Remote-sensing Data"],"name":"mars_2020_terrain_relative_navigation_hirise_orthorectified_image_mosaic","onlink":"https://astrogeology.usgs.gov/search/map/mars_2020_terrain_relative_navigation_hirise_orthorectified_image_mosaic","pubdate":"2020-07-24","thumb":"https://astrogeology.usgs.gov/ckan/dataset/cee23e0f-a7fb-4695-b1c8-f295f09a305f/resource/f9affb52-645e-4c81-b4c6-1a23dcb4ec54/download/jez_hirise_soc_006_orthomosaic_25cm_eqc_latts0_lon0_first_100.jpg","title":"Mars 2020 Terrain Relative Navigation HiRISE Orthorectified Image Mosaic"},{"abstract":"This new work represents a seamless, globally consistent, 1:5,000,000-scale geologic map derived from the six digitally renovated geologic maps (see Source Online Linkage below). The goal of this project was to create","geoform":["Geologic Map"],"name":"unified_geologic_map_of_the_moon_1_5m_2020","onlink":"https://astrogeology.usgs.gov/search/map/unified_geologic_map_of_the_moon_1_5m_2020","pubdate":"2020-03-03","thumb":"https://astrogeology.usgs.gov/ckan/dataset/85606456-bb36-4515-b3b9-880567f96a23/resource/0cabdce9-7753-43ac-ba34-a6551fa6bc7c/download/unified_geologic_map_of_the_moon_100.jpg","title":"Unified Geologic Map of the Moon, 1:5M, 2020"},{"abstract":"In early 2019, NASA's OSIRIS-REx (Origins, Spectral Interpretation, Resource Identification, and SecurityRegolith Explorer) mission surveyed asteroid (101955) Bennu with a collection of instruments, including the OSIRIS-REx Camera Suite (OCAMS) PolyCam imager. Using","geoform":["Global Mosaic"],"name":"bennu_osiris_rex_ocams_global_pan_mosaic_5cm","onlink":"https://astrogeology.usgs.gov/search/map/bennu_osiris_rex_ocams_global_pan_mosaic_5cm","pubdate":"2020-02-26","thumb":"https://astrogeology.usgs.gov/ckan/dataset/1207ce04-efa6-4c3c-a7ad-13fd6b2af827/resource/a979ae3f-6e6b-49f2-b111-78f077ea6a88/download/thumb.png","title":"Bennu OSIRIS-REx OCAMS Global PAN Mosaic 5cm"},{"abstract":"<b>Product Information:</b> This is an (ortho-) mosaic map of the Apollo 17 landing site (L15K 20.2/30.7East COMT). The map includes nomenclature, elevation contours, the astronauts' major geology stops, and rover traverses. It","geoform":["Landing Site Map","Raster Data","Remote-sensing Data","Topographic Map","Traverse Map","Vector Data"],"name":"moon_apollo_17_lroc_nac_landing_site_orthomosaic_50cm","onlink":"https://astrogeology.usgs.gov/search/map/moon_apollo_17_lroc_nac_landing_site_orthomosaic_50cm","pubdate":"2018-05-01","thumb":"https://astrogeology.usgs.gov/ckan/dataset/2f509e69-cd20-4638-ab63-618135c776b3/resource/0f74727d-2040-45c4-8ebb-2d26f8232206/download/image01_thumb.jpg","title":"Moon Apollo 17 LROC NAC Landing Site Orthomosaic 50cm"}],"title":"","total":1643}