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How does your smartphone
know exactly where you are?
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The answer lies 12,000 miles
over your head
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in an orbiting satellite that keeps time
to the beat of an atomic clock
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powered by quantum mechanics.
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Phew.
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Let's break that down.
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First of all, why is it so important
to know what time it is on a satellite
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when location is what
we're concerned about?
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The first thing
your phone needs to determine
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is how far it is from a satellite.
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Each satellite constantly
broadcasts radio signals
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that travel from space to your phone
at the speed of light.
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Your phone records
the signal arrival time
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and uses it to calculate
the distance to the satellite
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using the simple formula,
distance = c x time,
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where c is the speed of light
and time is how long the signal traveled.
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But there's a problem.
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Light is incredibly fast.
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If we were only able to calculate
time to the nearest second,
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every location on Earth, and far beyond,
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would seem to be the same
distance from the satellite.
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So in order to calculate that distance
to within a few dozen feet,
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we need the best clock ever invented.
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Enter atomic clocks,
some of which are so precise
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that they would not gain or lose a second
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even if they ran
for the next 300 million years.
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Atomic clocks work
because of quantum physics.
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All clocks must have a constant frequency.
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In other words, a clock must carry out
some repetitive action
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to mark off equivalent increments of time.
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Just as a grandfather clock
relies on the constant swinging
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back and forth of a pendulum
under gravity,
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the tick tock of an atomic clock
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is maintained by the transition
between two energy levels of an atom.
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This is where quantum physics
comes into play.
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Quantum mechanics
says that atoms carry energy,
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but they can't take on
just any arbitrary amount.
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Instead, atomic energy
is constrained to a precise set of levels.
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We call these quanta.
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As a simple analogy,
think about driving a car onto a freeway.
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As you increase your speed,
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you would normally continuously go
from, say, 20 miles/hour up to 70 miles/hour.
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Now, if you had a quantum atomic car,
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you wouldn't accelerate
in a linear fashion.
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Instead, you would instantaneously jump,
or transition, from one speed to the next.
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For an atom, when a transition
occurs from one energy level to another,
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quantum mechanics says
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that the energy difference
is equal to a characteristic frequency,
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multiplied by a constant,
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where the change in energy is equal to
a number, called Planck's constant,
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times the frequency.
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That characteristic frequency
is what we need to make our clock.
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GPS satellites rely on cesium and rubidium
atoms as frequency standards.
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In the case of cesium 133,
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the characteristic clock frequency
is 9,192,631,770 Hz.
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That's 9 billion cycles per second.
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That's a really fast clock.
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No matter how skilled a clockmaker may be,
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every pendulum, wind-up mechanism
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and quartz crystal resonates
at a slightly different frequency.
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However, every cesium 133 atom
in the universe
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oscillates at the same exact frequency.
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So thanks to the atomic clock,
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we get a time reading accurate
to within 1 billionth of a second,
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and a very precise measurement
of the distance from that satellite.
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Let's ignore the fact that you're almost
definitely on Earth.
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We now know that you're at a fixed
distance from the satellite.
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In other words, you're somewhere
on the surface of a sphere
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centered around the satellite.
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Measure your distance
from a second satellite
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and you get another overlapping sphere.
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Keep doing that,
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and with just four measurements,
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and a little correction
using Einstein's theory of relativity,
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you can pinpoint your location to exactly
one point in space.
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So that's all it takes:
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a multibillion-dollar
network of satellites,
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oscillating cesium atoms,
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quantum mechanics,
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relativity,
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a smartphone,
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and you.
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No problem.
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