Hi, this is Wayne again with a topic “How Does LIGHT Carry Data? – Fiber Optics Explained”.
If you’ve ever built a tree, fort, you’ve probably also tried to send a secret message to your friend using Morse code and a flashlight and fundamentally fiber-optic. Networking works in the same way. Encoding data impulses of light that travel around the world carrying our phone calls business conferences and important Internet data, but now hold on a second. How exactly do you send light over great distances and still manage to extract information from it? I mean fiber optic cables have to carry light for literally thousands of miles like across oceans.
Yet if you’ve ever signed a flashlight down a long hallway, you’ll know that over any more than a short distance, the light scatters and eventually becomes too dim to make out. Well, that is where optical fibers come in those really skinny tubes that make your Christmas tree. Look nice without having to string up any messy lights, have some special characteristics that allow them to work over incredible distances.
The main way that fiber optics behave differently than your flashlights is that they take advantage of a physical phenomenon called total internal reflection. You see a fiber optic system doesn’t just shine light down any random hollow tube. Instead, optical cables are made up of a core of glass or plastic, surrounded by an outer layer called cladding.
Both the glass and the cladding have an inherent property called a refractive index, which is basically a measure of how fast light can travel through something for the system to work properly. The cladding needs to have a slightly lower index of refraction than the core. Now sometimes this is achieved by using pure glass, that is, silicon dioxide for the core, and then doping, the cladding with chemicals to lower its refractive index, while other times the core itself can be doped to raise the same value either way.
This different means that, if light hits the cladding at a shallow enough angle, it will be completely reflected at the same angle instead of passing through the cladding. That means that it can continue on down the fiber in a Ziggs pattern in definitely here. Well, not quite although in theory, the optical signal should just keep going all the way until it reaches the other end of the fiber. The pesky real world always has a way of throwing a wrench in the pudding, no matter how high-end and pure an optical cable is. There will always be some imperfections, even if they’re so small, that you could only see them at the molecular level, and these will cause some of that light to scatter weakening the signal over distance until eventually it can’t be understood by the equipment at the other end. So to combat this long, distance fiber runs, are assisted by repeaters or amplifiers. A repeater gets placed at a point down the fiber, where the signal will have weakened significantly, but it’s still strong enough to be read once the light hits the repeater. It’S turned into the corresponding electronic signal, which is then turned back into light, much as it was at the origination point and then sent along on its merry way.
Repeaters come with a latency and a complexity cost though so many modern long-distance systems now use amplifiers. Instead, these gadgets have optical fibers, which are doped with chemicals that directly amplify light when the weakened signal hits them. So the ions in the fibers themselves will re-emit the same signal but much more strongly than what came in and it continues down the cable. In this way, optical fiber runs can be designed to be really long, making them a more viable choice for long-distance communication than copper optical fiber is not only more cost effective than copper wiring, it’s more power efficient, and it even goes farther without requiring a boost.
Also because it’s thinner and doesn’t cause electromagnetic interference to the cables around it, it’s common to bundle a bunch of optical fibers, each of which can carry multiple wavelengths of light into one large cable, making it possible to transmit enormous amounts of data without taking up too Much space, this versatility means that far optics have found uses outside of just communication, such as an endoscopy, where their flexibility allows a user to light up and view inside very hard to reach spaces. This is useful in fields like engineering, plumbing and even medicine, speaking of which I got to run and get to a doctor’s appointment that hopefully doesn’t involve sticking a fiber-optic scope up somewhere, embarrassing. Oh, I know what the doctor ordered this message from our sponsor becoming great. At math, science and computer science doesn’t have to be dull. Brilliant is a problem-solving website and app with a hands-on approach with over 50 interactive courses. Brilliant courses have storytelling code, writing, interactive challenges and problems to solve and with brilliant.
You get to unravel concepts bit by bit and build up to an interesting conclusion and discover deep truths in unexpected places, for example, check out their new course on differential equations for you’ll, learn about the Lorenz equations and experience tons of real-world examples. The first 200 of you to click, the link in the description will get 20 % off an annual premium subscription. So thanks for watching guys like dislike, leave a comment.
If you have a suggestion for a future fast as possible – and I will see you next time – .