1 00:00:00,060 --> 00:00:04,240 [chimes] 2 00:00:04,260 --> 00:00:08,270 3 00:00:08,290 --> 00:00:12,340 My name's Bryan Blair, I'm an instrument scientist in the 4 00:00:12,360 --> 00:00:16,430 laser remote sensing laboratory at Goddard. 5 00:00:16,450 --> 00:00:20,640 LVIS is a high altitude, laser swath 6 00:00:20,660 --> 00:00:24,820 mapping system, so it's designed to measure the surface of the Earth. 7 00:00:24,840 --> 00:00:28,960 So whether it's the topography, the elevations, 8 00:00:28,980 --> 00:00:33,090 of the surface, or the structure of vegetation, or the 9 00:00:33,110 --> 00:00:37,140 changes that are happening to the surface, whether they're subtle changes 10 00:00:37,160 --> 00:00:41,220 for example, volcanic sources, underground magma chambers, or 11 00:00:41,240 --> 00:00:45,280 very dynamic surfaces like glaciers, for example, 12 00:00:45,300 --> 00:00:49,330 so it's a unique capability because we can map 13 00:00:49,350 --> 00:00:53,510 incredibly large areas from a high altitude aircraft 14 00:00:53,530 --> 00:00:57,690 so we can map actually, we are getting to the point where we can map 15 00:00:57,710 --> 00:01:01,880 an entire nation with a laser system, so it's quite good. 16 00:01:01,900 --> 00:01:06,060 For IceBridge, 17 00:01:06,080 --> 00:01:10,260 there was a number of goals of IceBridge. 18 00:01:10,280 --> 00:01:14,320 Namely, to keep track of what changes were happening 19 00:01:14,340 --> 00:01:18,360 to the ice sheets in between the two ICESat missions, ICESat one and ICESat-2, 20 00:01:18,380 --> 00:01:22,500 so we actually get out there on a yearly basis and monitor the 21 00:01:22,520 --> 00:01:26,630 changes. And then there was a more long-term goal, 22 00:01:26,650 --> 00:01:30,650 which would be to help tie those two satellite missions together. 23 00:01:30,670 --> 00:01:34,730 So in one aspect you'd be looking at individual 24 00:01:34,750 --> 00:01:38,800 glaciers and in the other you'd actually be trying to lay out large grid patterns 25 00:01:38,820 --> 00:01:42,850 all over Greenland so that you could look at the changes over 26 00:01:42,870 --> 00:01:46,900 ten or twenty years. And it would contribute to that. So what LVIS brings, 27 00:01:46,920 --> 00:01:51,080 uniquely, is the ability to cover enormous 28 00:01:51,100 --> 00:01:55,190 areas very cost effectively. 29 00:01:55,210 --> 00:01:59,390 What we've been doing so far with IceBridge is going back at a 30 00:01:59,410 --> 00:02:03,560 a stable time in the ice sheets. In the spring for example in Greenland we 31 00:02:03,580 --> 00:02:07,770 go in the March April May time period because the 32 00:02:07,790 --> 00:02:11,950 drastic changes, the seasonal melt, the accumulation 33 00:02:11,970 --> 00:02:16,110 from the winter have sort of stabilized, so we can go back once a year 34 00:02:16,130 --> 00:02:20,260 and look at those long term trends in those ice sheets. 35 00:02:20,280 --> 00:02:24,420 So what we're doing this fall, we're going to see a six-month 36 00:02:24,440 --> 00:02:28,540 change. And that six-month change is more related to those seasonal effects. 37 00:02:28,560 --> 00:02:32,670 The summer melt that's been occurring. So we can go in 38 00:02:32,690 --> 00:02:36,780 there and look at glaciers and some of the interior of the ice sheets 39 00:02:36,800 --> 00:02:40,870 and see how much melt has occurred. 40 00:02:40,890 --> 00:02:44,930 And with LVIS and all the spring mapping that we did we'll be able to look 41 00:02:44,950 --> 00:02:48,960 at that change over large areas. 42 00:02:48,980 --> 00:02:53,020 One of the really unique technologies about LVIS is 43 00:02:53,040 --> 00:02:57,200 there's some optical limitations to telescopes. So a telescope can only be 44 00:02:57,220 --> 00:03:01,390 so large, collect so much light, and see 45 00:03:01,410 --> 00:03:05,420 so big of an angular field of view. So with LVIS, 46 00:03:05,440 --> 00:03:09,600 we actually have a mechanical, a very unique lightweight scanning system 47 00:03:09,620 --> 00:03:13,790 that actually scans the field of view of the telescope as constantly as we're flying along, 48 00:03:13,810 --> 00:03:17,980 so it's actually sweeping back and forth about 10 or 20 times 49 00:03:18,000 --> 00:03:22,190 a second. And then within that field of view we're scanning our laser very 50 00:03:22,210 --> 00:03:26,360 quickly to make that full images. So it's a really, it's a unique 51 00:03:26,380 --> 00:03:30,540 technology that allows us to have a large telescope which you need to be able to 52 00:03:30,560 --> 00:03:34,720 collect all the photons and the reflected light from the surface, efficiently, 53 00:03:34,740 --> 00:03:38,830 so it's a large collecting area, with a large 54 00:03:38,850 --> 00:03:42,900 field of view. 55 00:03:42,920 --> 00:03:46,970 NASA Wallops Flight Facility has recently acquired a C-130 56 00:03:46,990 --> 00:03:51,030 aircraft. It's a large, turboprop aircraft. 57 00:03:51,050 --> 00:03:55,070 It can fly at 30,000 feet, it has pretty good endurance, so that what 58 00:03:55,090 --> 00:03:59,250 we're going to put LVIS on - the two LVISes on - this year. 59 00:03:59,270 --> 00:04:03,430 There's a lot of capacity of this aircraft. You could actually fly quite a number of instruments 60 00:04:03,450 --> 00:04:07,610 and we'll be the first to use it for NASA. 61 00:04:07,630 --> 00:04:11,790 [beep beep, beep beep] 62 00:04:11,810 --> 00:04:16,136