1 00:00:00,010 --> 00:00:09,780 [ ambient drone ] 2 00:00:09,800 --> 00:00:13,600 [ music ] 3 00:00:13,620 --> 00:00:17,680 LRO is this amazing spacecraft that has seven science instruments on it, 4 00:00:17,700 --> 00:00:22,440 and it's been in orbit around the Moon since June of 2009. 5 00:00:22,460 --> 00:00:27,240 And it's collecting all sorts of data to help NASA make really good decisions in the future 6 00:00:27,260 --> 00:00:33,980 about where to send robotic spacecraft and humans, and to address fundamentally-important science questions 7 00:00:34,000 --> 00:00:38,030 not only about the Moon, but about the solar system in general. 8 00:00:38,050 --> 00:00:42,980 I'm Mark Robinson, and I'm the principal investigator of the Lunar Reconnaissance Orbiter Camera. 9 00:00:43,000 --> 00:00:45,630 10 00:00:45,650 --> 00:00:51,180 Okay, what is LROC? That's a great question. Sounds like one camera, Lunar Reconnaissance Orbiter Camera, but it's not. 11 00:00:51,200 --> 00:00:56,030 It's actually three cameras. There are two identical narrow angle cameras that are very high resolution, 12 00:00:56,050 --> 00:01:01,110 they have pixels about this big, 50 centimeters, and it was designed so that you could look 13 00:01:01,130 --> 00:01:05,710 at a human scale on the surface to find safe and engaging landing sites. 14 00:01:05,730 --> 00:01:09,260 Then there's a third camera, wide angle camera, which is literally about this big. 15 00:01:09,280 --> 00:01:13,700 It maps the Moon in UV and visible wavelengths, and its key purpose is to 16 00:01:13,720 --> 00:01:18,980 look at compositional differences for both scientific and resource evaluation. 17 00:01:19,000 --> 00:01:23,980 18 00:01:24,000 --> 00:01:27,780 It's not easy to find new impact craters because most of them are very small. 19 00:01:27,800 --> 00:01:33,760 The only way we can really do this is if we have a before image and an after image, and we've been in orbit for four years now. 20 00:01:33,780 --> 00:01:40,480 So what we're doing now is we're going back to images that were taken in the first year or two, put them on a computer screen, and blink them. 21 00:01:40,500 --> 00:01:43,240 And then it becomes really obvious, "Oh, look, there's a new crater there!" 22 00:01:43,260 --> 00:01:48,400 because it wasn't in the before, it's in the after, before after, and we call these temporal pairs. 23 00:01:48,420 --> 00:01:54,730 So now we have several thousand pairs, and to sit down and look at every single pixel in all those images 24 00:01:54,750 --> 00:01:58,280 would probably take one person, you know, ten or twenty or thirty years. 25 00:01:58,300 --> 00:02:04,110 So we started working on an algorithm, or a computer program, that searches the images by using a little template, 26 00:02:04,130 --> 00:02:10,480 the before and after pairs, and it automatically finds them. It gets like about a 90% success rate. 27 00:02:10,500 --> 00:02:13,980 So far we've found hundreds of changes on the surface. 28 00:02:14,000 --> 00:02:18,680 Many of them are too small to really know for sure if they're craters or if they're secondary craters, 29 00:02:18,700 --> 00:02:23,630 but we have found over 25 that are absolutely, positively confirmed craters, 30 00:02:23,650 --> 00:02:30,780 you can see the rim and the ejecta, and we've also made this amazing discovery that we find secondary craters related. 31 00:02:30,800 --> 00:02:36,660 32 00:02:36,680 --> 00:02:42,210 There was a bright flash that was recorded by a video camera by a team at Marshall Space Flight Center, 33 00:02:42,230 --> 00:02:47,110 and it was the brightest flash they recorded so it must be therefore one of the biggest craters, 34 00:02:47,130 --> 00:02:50,800 and so they were really interested for us to take a picture, can you see the crater? 35 00:02:50,820 --> 00:02:54,730 Because they predicted how big it was going to be based on the energy but this is all a model, 36 00:02:54,750 --> 00:02:57,980 and so it's a great opportunity to actually calibrate their model. 37 00:02:58,000 --> 00:03:02,280 So we took a picture centered on their coordinates, and we didn't find a crater. 38 00:03:02,300 --> 00:03:08,310 We found these enigmatic little splotches, there was something...disturbance of the soil 39 00:03:08,330 --> 00:03:11,280 that wasn't in the original image, but we didn't know what it was. 40 00:03:11,300 --> 00:03:15,880 So we thought, okay, well their coordinates are off a little bit, because their pixels are really big from their camera, 41 00:03:15,900 --> 00:03:18,780 in fact their pixels are bigger than our image footprints. 42 00:03:18,800 --> 00:03:24,030 So we said, okay, no problem we'll move over to the west and we'll take a - you know, we're building up a mosaic. 43 00:03:24,050 --> 00:03:30,200 So the next month comes around, we take a picture and we do the same thing, look at the before, look at the after image: no crater. 44 00:03:30,220 --> 00:03:36,680 But more of these splotches...but also in that image we saw what looked like very faint rays, 45 00:03:36,700 --> 00:03:39,830 and we thought, "Boy, I wonder if those are actually rays from a crater?" 46 00:03:39,850 --> 00:03:44,680 So we just did this simple exercise of drawing lines and see where they converged, 47 00:03:44,700 --> 00:03:47,780 and then so the next month we came around, remember this is the third opportunity, 48 00:03:47,800 --> 00:03:52,800 we center the field of view of the camera right on that latitude-longitude, boom take another picture, 49 00:03:52,820 --> 00:03:57,330 comes down and there it is: beautiful 18-meter-diameter crater. 50 00:03:57,350 --> 00:04:02,810 And then we started looking and now we've got three of these, and there's hundreds of these little splotches that we're finding, 51 00:04:02,830 --> 00:04:08,130 these rays, and then we have the big picture: you could see that the splotches are actually lined up. 52 00:04:08,150 --> 00:04:13,480 These very small clods of ejecta were thrown out ten, twenty, thirty kilometers away, 53 00:04:13,500 --> 00:04:19,500 that's thirty-thousand meters compared to an 18-meter-diameter crater, so it's a very exciting discovery. 54 00:04:19,520 --> 00:04:22,930 [ music ] 55 00:04:22,950 --> 00:04:37,057 [ satellite beeping ]