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The Internet: Wires, Cables, & Wifi

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    The Internet | Wires, Cables, and Wi-Fi
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    My name is Tess Winlock, I'm a software engineer
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    at Google. Here's a question: How does a picture,
    text message, or email get sent from one device
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    to another? It isn't magic, it's the Internet.
    A tangible, physical system made to move information.
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    The Internet is a lot like the postal service,
    but the physical stuff that gets sent is a
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    little bit different. Instead of boxes and
    envelopes, the Internet ships binary information.
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    Information is made of bits. A bit can be
    described as any pair of opposites: on or
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    off, yes or no. We typically use a 1 meaning
    on, or a 0 meaning off. Because a bit has two
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    possible states we call it binary code. 8
    bits strung together makes 1 byte. 1000 bytes
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    all together is a kilobyte. 1000 kilobytes
    is a megabyte. A song is typically encoded
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    using about 3-4MB. It doesn't matter if it's
    a picture, a video, or a song, everything
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    on the Internet is represented and sent around
    as bits. These are the atoms of information.
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    But it's not like we're physically sending
    1s and 0s from one place to another or one
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    person to another. So what is the physical
    stuff that actually gets sent over the wires
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    and the airways? Well, let's look at a small
    example here of how humans can physically
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    communicate to send a single bit of information
    from one place to another. Let's say that
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    we can turn on a light for a 1 or off for
    0. Or use beeps or similar sorts of things
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    to Morse code. These methods work but they're
    really slow, error prone, and totally dependent
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    upon humans. What we really need is a machine.
    Throughout history, we've built many systems
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    that can actually send this binary information
    through different types of physical mediums.
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    Today, we physically send bits by electricity,
    light, and radio waves. To send a bit via electricity,
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    imagine that you have two lightbulbs connected
    by a copper wire. If one device operator turns
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    on the electricity then the lightbulb lights
    up. No electricity, then no light. If the
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    operators on both ends agree that light on
    means 1 and light off means 0, then we have
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    a system for sending bits of information from
    one person to another using electricity. But
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    we have kinda a small problem, if you need
    to send a 0 five times in a row, well how
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    can you do that in such a way that either
    person can actually count the number of 0s?
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    Well the solution is to introduce a clock
    or a timer. The operators can agree that the
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    sender will send 1 bit per second and the
    receiver will sit down and record every single
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    second and see what's on the line. To send
    five 0s in a row, you just turn off the light,
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    wait 5 seconds, the person at the other end
    of the line will write down all 5 seconds.
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    For five 1s in a row, switch it on, wait 5 seconds,
    write down every second. Obviously we'd like
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    to send things a little bit faster than one
    bit per second, so we need to increase our
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    bandwidth - the maximum transmission capacity
    of a device. Bandwidth is measured by bitrate,
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    which is the number of bits that we can actually
    send over a given period of time usually measured
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    in seconds. A different measure of speed is
    the latency, or the amount of time it takes
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    for one bit to travel from one place to another,
    from the source to the requesting device.
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    In our human analogy, one bit per second was
    pretty fast but kinda hard for a human to
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    keep up with. Let's say that you actually
    want to download a 3MB song in 3 seconds,
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    at 8 million bits per megabyte that means
    a bit rate of about 8 million bits per second.
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    Obviously, humans can't send or receive 8
    million bits per second but a machine could
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    do that just fine. But now there's also the
    question of what sort of cable to send these
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    messages over and how far the signals can
    go. With an ethernet wire, the kind that you
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    find in your home, office, or school you see
    measurable signal loss or interference over
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    just a few hundred feet. For the Internet
    to work all around the world, we need to have
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    an alternative method to send bits really
    long distances. We're talking like across
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    oceans. So what else can we use? What do we
    know that moves a lot faster than just electricity
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    through a wire? Light. We can actually send
    bits as light beams from one place to another
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    using a fiber optic cable. A fiber optic cable
    is a thread of glass engineered to reflect
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    light. When you send a beam of light down
    the cable, light bounces up and down the length
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    of the cable until it is received on the other
    end. Depending on the bounce angle, we can
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    actually send multiple bits simultaneously,
    all of them traveling at the speed of light.
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    So fiber is really really fast. But more importantly
    the signal doesn't really degrade over long
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    distances. This is how you can go hundreds
    of miles without signal loss. This is why
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    we use fiber optic cables across the ocean
    floors to connect one continent to another.
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    In 2008 there was a cable that was actually
    cut near Alexandria, Egypt which really interrupted
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    the Internet for most of the Middle East and
    India. So we take this Internet thing for
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    granted but it's really a pretty fragile,
    physical system. And fiber is awesome but
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    it's also really expensive and hard to work
    with. For most purposes, you're going to find
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    copper cable. But how do we move things without
    wires? How do we send things wirelessly? Radio.
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    Wireless bit sending machines typically use
    a radio signal to send bits from one place
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    to another. The machines have to actually
    translate the 1s and 0s into radio waves of
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    different frequencies. The receiving machines
    reverse the process and convert it back into
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    binary on your computer. So wireless has made
    our Internet mobile. But a radio signal doesn't
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    travel all that far before it gets completely
    garbled. This way you can't really pick up
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    a Los Angeles radio station in Chicago. As
    great as wireless is, today it still relies
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    on the wired Internet. If you're in a coffee
    shop using wifi, then the bits get sent to
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    this wireless router and then are transferred
    through the physical wire to travel the really
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    long distances of the Internet. The physical
    method for sending bits may change in the
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    future, whether its lasers sent between satellites,
    or radio waves from balloons, or drones, but
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    the underlying binary representation of information
    and the protocols for sending that information
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    and receiving that information have pretty
    much stayed the same. Everything on the Internet,
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    whether it's words, emails, images, cat videos,
    puppy videos, all come down to these 1s and
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    0s being delivered by electronic pulses, light
    beams, radio waves, and lots and lots of love.
Title:
The Internet: Wires, Cables, & Wifi
Description:

This educational video introduces how the physical infrastructure of the Internet moves information.

See more at Code.org/educate/csp

Presented by Tess Winlock / Software Engineer at Google

Special Thanks:
Tess Winlock,
Abby Huang
Bemnet Assefa
Saloni Parikh
archive.org
wikimedia
submarinecablemap.com
Google Earth
Wikipedia

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Video Language:
English
Duration:
06:41

English subtitles

Revisions

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