WEBVTT - How do they backlight LCD screens? 0:00:00.520 --> 0:00:03.800 Welcome to Brainstuff from house stuff works dot com where 0:00:03.840 --> 0:00:15.000 smart happens. Him Marshall Brain with today's question, how do 0:00:15.080 --> 0:00:20.000 they backlight l c D screens? Obviously, these screens are 0:00:20.120 --> 0:00:23.239 brightly backlit. A lot of people use their cell phones 0:00:23.320 --> 0:00:26.960 or their laptops as flashlights, so they're using the backlights 0:00:27.000 --> 0:00:30.560 to produce usable light. How do they make these backlights 0:00:30.600 --> 0:00:34.760 so bright and so consistent? Currently? There are two technologies 0:00:34.800 --> 0:00:39.760 for backlighting the screens. Today, most computer liquid crystal display 0:00:39.840 --> 0:00:42.720 or l c D panels are lit with built in 0:00:42.800 --> 0:00:47.000 fluorescent tubes that are placed either above, beside, or sometime 0:00:47.080 --> 0:00:50.960 directly behind the l c D panel. A white diffusion 0:00:51.040 --> 0:00:54.520 panel behind the l c D redirects and scatters the 0:00:54.640 --> 0:00:58.840 light evenly, and that ensures a uniform display. This is 0:00:58.960 --> 0:01:02.680 known as the BacT light. A fluorescent light is most 0:01:02.720 --> 0:01:06.559 often a long, straight glass tube that produces white light. 0:01:07.040 --> 0:01:10.800 Inside the glass tube, there's a low pressure mercury vapor. 0:01:11.160 --> 0:01:15.839 When ionized, mercury vapor emits ultra violet light. Human eyes 0:01:15.920 --> 0:01:19.400 aren't sensitive to ultra violet light, although the human skin is. 0:01:19.480 --> 0:01:22.840 That's how we get sunburns. The inside of the fluorescent 0:01:22.920 --> 0:01:25.800 tube is coated with a phosphor that's going to turn 0:01:25.920 --> 0:01:29.000 that ultra violet light into something human beings can see. 0:01:29.520 --> 0:01:33.080 Phosphor is a substance that can accept energy in one 0:01:33.200 --> 0:01:36.560 form and emit the energy in the form of visible light. 0:01:36.920 --> 0:01:40.119 For example, energy from high speed electrons in a TV 0:01:40.280 --> 0:01:43.759 tube are absorbed by the phosphors on a normal CRT 0:01:44.000 --> 0:01:47.440 screen and then turned into light. The light that we 0:01:47.560 --> 0:01:50.840 see from a fluorescent tube is the light given off 0:01:50.920 --> 0:01:55.160 by the phosphor coating inside the tube. The phosphor fluoresces 0:01:55.240 --> 0:01:59.840 when energized, hence the name. A typical laptop display uses 0:02:00.040 --> 0:02:04.080 a tiny cold cathode fluorescent lamp, also known as a 0:02:04.240 --> 0:02:08.160 CCFL for the back light. One of these small tubes 0:02:08.240 --> 0:02:12.080 is able to provide an incredibly bright white light source 0:02:12.400 --> 0:02:14.840 that can be diffused by the panel behind the l 0:02:14.880 --> 0:02:19.240 c D. In addition to providing ample light, ccfl's do 0:02:19.360 --> 0:02:23.119 not rise far above the ambient temperature. This makes them 0:02:23.160 --> 0:02:26.080 ideal for l c D panels since the light source 0:02:26.240 --> 0:02:29.560 is close to the other components that could be ruined 0:02:29.560 --> 0:02:33.520 by excessive heat. One amazing thing about these lamps is 0:02:33.560 --> 0:02:38.640 their incredibly small size. They are extremely thin, about the 0:02:38.760 --> 0:02:42.080 size of the graphite in a wooden pencil, and the 0:02:42.160 --> 0:02:45.639 board that drives the lamp is very small as well. However, 0:02:45.800 --> 0:02:48.440 it's not that hard to break these lamps, which is 0:02:48.480 --> 0:02:51.480 why you're display maygo dark if you drop your laptop. 0:02:51.840 --> 0:02:55.200 The technology that's coming on strong today and is likely 0:02:55.280 --> 0:02:58.680 to completely replace these fluorescent lamps in the future is 0:02:58.919 --> 0:03:02.320 LED technology. G l e d s are more rugged 0:03:02.320 --> 0:03:05.720 than fluorescent lamps, they use less power than fluorescent lamps, 0:03:05.800 --> 0:03:09.160 and they're more adjustable than fluorescent lamps. But they also 0:03:09.200 --> 0:03:12.360 have this one other really interesting feature that's now used 0:03:12.400 --> 0:03:15.080 on some of the high end l e ED backlit 0:03:15.639 --> 0:03:18.079 h D t V screens, and that is you can 0:03:18.120 --> 0:03:20.440 turn the l e d s in the backlighting on 0:03:20.560 --> 0:03:23.400 and off separately, so you can have an array of 0:03:23.480 --> 0:03:25.760 white l e d s that are behind the l 0:03:25.840 --> 0:03:28.520 c D panel, and in the areas that are supposed 0:03:28.560 --> 0:03:31.760 to be dark, you can turn down or turn off 0:03:31.880 --> 0:03:34.320 those l c d s. So when you look at 0:03:34.680 --> 0:03:37.040 big l c D h D t vs today and 0:03:37.040 --> 0:03:40.680 you see them with super high contrast ratios like three 0:03:40.680 --> 0:03:44.120 million to one or ten million to one contrast ratios, 0:03:44.480 --> 0:03:47.680 that's being done by having a panel of l e 0:03:47.800 --> 0:03:50.720 d s that are behind the l c D panel, 0:03:51.120 --> 0:03:53.640 and those l e d s are being controlled by 0:03:53.680 --> 0:03:57.920 the TV signal to turn parts of the screen completely dark. 0:04:00.120 --> 0:04:02.520 More on this and thousands of other topics, visit how 0:04:02.560 --> 0:04:04.840 stuff works dot com and don't forget to check out 0:04:04.880 --> 0:04:06.760 the brain stuff blog on the how stuff works dot 0:04:06.800 --> 0:04:09.400 com home page. You can also follow brain stuff on 0:04:09.400 --> 0:04:12.320 Facebook or Twitter at brain stuff H. S W