{ "count": 8, "next": null, "previous": null, "results": [ { "id": 5124, "url": "https://svs.gsfc.nasa.gov/5124/", "result_type": "Visualization", "release_date": "2023-07-10T14:00:00-04:00", "title": "The 2023 Annular Solar Eclipse", "description": "The path of annularity and partial contours crossing the U.S. for the 2023 annular solar eclipse occurring on October 14, 2023. || eclipse_map_2023_QR_1920.png (1920x960) [3.4 MB] || eclipse_map_2023_QR_10800.png (10800x5400) [77.3 MB] || eclipse_map_2023_QR_5400.png (5400x2700) [23.1 MB] || eclipse_map_2023_QR_1920_searchweb.png (320x180) [111.9 KB] || eclipse_map_2023_QR_1920_thm.png (80x40) [7.2 KB] || eclipse_map_2023_QR.png (22500x11250) [129.8 MB] || the-2023-annular-solar-eclipse.hwshow [302 bytes] || ", "hits": 94 }, { "id": 4574, "url": "https://svs.gsfc.nasa.gov/4574/", "result_type": "Visualization", "release_date": "2017-05-31T10:00:00-04:00", "title": "Temperature, Reflectance Point to Frost near the Moon's Poles", "description": "A view of the south pole of the Moon showing where reflectance and temperature data indicate the possible presence of surface water ice. Includes music and narration. Music by Killer Tracks: Full Charge - Zubin Thakkar. || 4574_LROMoonFrost_YouTube.00780_print.jpg (1024x576) [236.8 KB] || 4574_LROMoonFrost_YouTube.mp4 (1920x1080) [75.8 MB] || 4574_LROMoonFrost_Facebook.mp4 (1280x720) [65.4 MB] || 4574_LROMoonFrost_Twitter.mp4 (1280x720) [11.8 MB] || 4574_LROMoonFrost_Facebook.webm (1280x720) [5.2 MB] || 4574_LROMoonFrost_MASTER.mov (1920x1080) [639.4 MB] || 4574_LroMoonFrost_Captions.en_US.srt [761 bytes] || 4574_LroMoonFrost_Captions.en_US.vtt [774 bytes] || 4574_LROMoonFrost_YouTube.mp4.hwshow [191 bytes] || ", "hits": 223 }, { "id": 4226, "url": "https://svs.gsfc.nasa.gov/4226/", "result_type": "Visualization", "release_date": "2014-06-18T00:00:00-04:00", "title": "Hyperwall: LOLA Slope Map", "description": "Part of the LOLA slope map of the Moon centered on the south pole. The prime meridian (0° longitude) is up. || slope_map_3x1_print.jpg (1024x345) [284.4 KB] || slope_map_3x1_web.jpg (320x108) [25.0 KB] || slope_map_3x1_searchweb.png (320x180) [154.5 KB] || slope_map_3x1_thm.png (80x40) [8.5 KB] || slope_map_3x1.tif (9600x3240) [80.7 MB] || slope_map_16x9.tif (5760x3240) [49.6 MB] || lola-slope-map.hwshow || ", "hits": 156 }, { "id": 10929, "url": "https://svs.gsfc.nasa.gov/10929/", "result_type": "Produced Video", "release_date": "2012-03-14T10:00:00-04:00", "title": "A Narrated Tour of the Moon", "description": "Although the moon has remained largely unchanged during human history, our understanding of it and how it has evolved over time has evolved dramatically. Thanks to new measurements, we have new and unprecedented views of its surface, along with new insight into how it and other rocky planets in our solar system came to look the way they do. See some of the sights and learn more about the moon here! || ", "hits": 70 }, { "id": 10930, "url": "https://svs.gsfc.nasa.gov/10930/", "result_type": "Produced Video", "release_date": "2012-03-14T10:00:00-04:00", "title": "Evolution of the Moon", "description": "From year to year, the moon never seems to change. Craters and other formations appear to be permanent now, but the moon didn't always look like this. Thanks to NASA's Lunar Reconnaissance Orbiter, we now have a better look at some of the moon's history. Learn more in this video!This entry contains the Evolution of the Moon video in mutliple formats, including stereoscopic 3D in both side-by-side and individual left/right channel versions. It also includes a narrated and non-narrated version. Each individual video is labeled to make it easier to find the version that works for you! || ", "hits": 192 }, { "id": 3587, "url": "https://svs.gsfc.nasa.gov/3587/", "result_type": "Visualization", "release_date": "2009-03-24T00:00:00-04:00", "title": "LRO Scouts for Safe Landing Sites - Stereoscopic Version", "description": "The Lunar Reconnaissance Orbiter (LRO) is NASA's scouting mission to prepare for a return to the moon. One of its primary objectives will be to assess the lunar terrain for areas that would provide safe landing sites for future missions, both manned and unmanned, that plan to touch down on the moon's surface. This video helps explain how LRO will accomplish its objective.This visualization is a modified 3D stereo version of animation entry:#10349: LRO Scouts for Safe Landing Sites.The raw stereoscopic visualization sequence used to create this narrated animation can be viewed and downloaded from entry: #3567: How LRO Will Find Safe Landing Sites on the Moon - Stereoscopic Version. || ", "hits": 84 }, { "id": 3567, "url": "https://svs.gsfc.nasa.gov/3567/", "result_type": "Visualization", "release_date": "2009-01-27T00:00:00-05:00", "title": "How LRO Will Find Safe Landing Sites on the Moon - Stereoscopic Version", "description": "The first attempt to land humans on the moon - Apollo 11 - was a triumph that almost ended in disaster. At just 400 feet from the lunar surface, with only about a minute's worth of fuel remaining, astronauts Neil Armstrong and Edwin 'Buzz' Aldrin saw that their ship's computer was taking them directly into a crater the size of a football field, strewn with SUV-sized boulders. They quickly took control from the computer, flew over the crater and touched down in a smoother area beyond, cutting the engine with just 30 seconds of fuel left. In general, good landing sites need to be level and free from large boulders that could damage or tip the spacecraft as it attempts to land. And it's up to the Lunar Reconaissance Orbiter (LRO) mission to make those landings as safe as possible. Astronauts will want to avoid places with steep slopes that could tip the spacecraft, so LRO includes a laser ranging system that will build an elevation map to show the contours of the polar surface. The instrument, called the Lunar Orbiter Laser Altimeter (LOLA ), records the time it takes for a laser pulse to travel from the spacecraft to the lunar surface and back to calculate the height of the lunar terrain. After a year in orbit aboard LRO, LOLA will have created an elevation map of the polar regions that is accurate to within a half-meter (20 inches) vertically and 50 meters (about 160 feet) horizontally. LRO will also use data from another instrument that measures temperatures to double-check the safe zone map. Temperatures change more rapidly in areas with loose materials (lots of rocks). By analyzing how quickly temperatures change in potential landing zones, planners using the instrument, named Diviner, can rule out areas that appear smooth but actually are likely to be rocky. LRO also carries a pair of eagle-eyed cameras, called the Narrow Angle Cameras (NACs) which together can take images that reveal details as small as a half-meter (almost 20 inches) over swaths 10 kilometers (about 6.2 miles) wide. As LRO orbits over the poles, the moon rotates beneath the spacecraft, and the NACs will gradually build up a detailed picture of the region. It will be used to identify safe landing zones free of large boulders and craters, allowing astronauts to avoid surprises like Apollo 11. LRO is being assembled and managed by NASA Goddard, and is scheduled to be launched in early 2009. NASA plans to have astronauts back on the moon by 2020. As astronauts close in on a new landing site late in the next decade, they can thank NASA Goddard's small robot scout for showing the safest approach. This visualization is a modified stereoscopic version of: #3533: How LRO Will Find Safe Landing Sites on the Moon The modifications applied in the production of the stereoscopic visualization include: extension of the time range of the animation, color adjustments, scale bar and text overlay treatment.The crater depicted in this visualization is ficticious and only intended for illustrative purposes. The visualization begins with the reveal of a digital elevation map showing sample lunar topography illustrating the kind of data that LRO's LOLA instrument will collect. From this topographic data level surface areas can be derived as the first step to determining safe landing sites. Next, an example temperature map of the lunar surface is revealed to show the sort of data Diviner will collect. Changes in surface temperature will help determine small rock hazards, since they retain and release heat at a different rate than the surrounding regolith. Large rock hazards can be found with LROC's surface imagery. Finally, removing rock hazard areas from level surface areas reveals potential safe landing sites for future lunar missions.In this page the visualization content is offered in various modes to accomodate different types of stereoscopic viewing, such as: Left and Right Eye separate, and Left and Right Eye side-by-side combined on the same frame. || ", "hits": 172 }, { "id": 3533, "url": "https://svs.gsfc.nasa.gov/3533/", "result_type": "Visualization", "release_date": "2008-09-02T00:00:00-04:00", "title": "How LRO Will Find Safe Landing Sites on the Moon (No Narration)", "description": "The first attempt to land humans on the moon - Apollo 11 - was a triumph that almost ended in disaster. At just 400 feet from the lunar surface, with only about a minute's worth of fuel remaining, astronauts Neil Armstrong and Edwin 'Buzz' Aldrin saw that their ship's computer was taking them directly into a crater the size of a football field, strewn with SUV-sized boulders. They quickly took control from the computer, flew over the crater and touched down in a smoother area beyond, cutting the engine with just 30 seconds of fuel left. In general, good landing sites need to be level and free from large boulders that could damage or tip the spacecraft as it attempts to land. And it's up to LRO to make those landings as safe as possible. Astronauts will want to avoid places with steep slopes that could tip the spacecraft, so LRO includes a laser ranging system that will build an elevation map to show the contours of the polar surface. The instrument, called the Lunar Orbiter Laser Altimeter (LOLA), records the time it takes for a laser pulse to travel from the spacecraft to the lunar surface and back to calculate the height of the lunar terrain. After a year in orbit aboard LRO, LOLA will have created an elevation map of the polar regions that is accurate to within a half-meter (20 inches) vertically and 50 meters (about 160 feet) horizontally. LRO will also use data from another instrument that measures temperatures to double-check the safe zone map. Temperatures change more rapidly in areas with loose materials (lots of rocks). By analyzing how quickly temperatures change in potential landing zones, planners using the instrument, named Diviner, can rule out areas that appear smooth but actually are likely to be rocky. LRO also carries a pair of eagle-eyed cameras, called the Narrow Angle Cameras (NACs) which together can take images that reveal details as small as a half-meter (almost 20 inches) over swaths 10 kilometers (about 6.2 miles) wide. As LRO orbits over the poles, the moon rotates beneath the spacecraft, and the NACs will gradually build up a detailed picture of the region. It will be used to identify safe landing zones free of large boulders and craters, allowing astronauts to avoid surprises like Apollo 11. LRO is scheduled to launch in 2009.For a 3D stereo version of this visualization, please visit animation #3567: How LRO Will Find Safe Landing Sites on the Moon - Stereoscopic versionFor a feature version of this visualization with narration and music, please visit Goddard Multimedia #10349: LRO Scouts for Safe Landing Sites || ", "hits": 147 } ] }