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  • If someone showed you a swinging pendulumlike this and asked you to calculate the pendulum’s

  • position at some point in the future, you might think it’d be relatively simple.

  • We should be able to predict that with the known laws of motion, right?

  • But this calculation is actually so complicated that it requires a relatively powerful computer.

  • And even if you did do this calculation, and then are offered slightly different initial

  • conditions, you would think that the output might also only be slightly different.

  • But instead, you get....chaos. Specifically, deterministic chaos.

  • See, as humans, were always trying to know more about how our world works, so we make

  • models.

  • For example, we have a bowling ball.

  • We know the weight of the bowling ball, the effect of gravity, the density of the air,

  • and the height of the balcony from which the bowling ball is to be dropped, and we can

  • put all those things together into a system of equations that we could use to tell us

  • things like how fast the bowling ball would fall, or the force with which it would impact

  • the ground.

  • That means we can also reasonably predict what might happen if any of those variables

  • were to change.

  • This is a deterministic systemthe behavior of certain variables is determined by their

  • known characteristics. But not a lot of the world is like the bowling ball example.

  • It’s a whole lot messier.

  • Take the weather.

  • Just think about all the things that go into making weathertemperature, humidity, wind

  • strength and direction, rotation of the earth, I mean the list is exhaustive.

  • We do have models for how all these many variables behave, but a perfect weather prediction would

  • require highly accurate measurements of all of the contributing variables over every square

  • inch of the piece of atmosphere were looking at. In a system like this, little measurement

  • errors can result in HUGE fluctuations of our calculated result.

  • Tiny changes of the input mean a LARGE variation of the output. Now don’t get me wrongthe

  • system is still deterministic.

  • The variables behave the way we expect them to based on their physical properties, so

  • it’s quite different from something that israndom’.

  • But it’s highly unpredictable and subject to vast variations.

  • The system may look disorganized, but there is a set of rules that apply to the chaos.

  • Deterministic chaosyou may have also heard of it as chaos theory or the butterfly effect.

  • Weather is actually how chaos theory was first discovered.

  • Edward Lorenz, a meteorologist at MIT, was performing an early weather simulation in

  • the 1960s, when he took a shortcut and used input numbers rounded to the nearest thousandth.

  • He expected to get slightly different results from the version with the full numbers...but

  • what he got instead was completely different. His investigation into this unexpected outcome

  • led to the birth of chaos theory, or the idea that chaotic systems magnify even the tiniest

  • changes in the component parts of that system.

  • Chaos can make it impossible to accurately predict the behavior of such a system at a

  • faraway point in time.

  • You know how you like to complain that the weather report is always wrong?

  • Blame chaos.

  • We can never measure the initial conditions precisely enough to accurately predict the

  • weather past a certain point in time.

  • That tiny bit off that we will always be is enough to produce a wildly inaccurate prediction

  • as the system progresses. If sensitivity to initial conditions is one defining factor

  • of a chaotic system, the other is something called a strange attractor.

  • Which is just as odd and exciting as it sounds.

  • Lorenz and his team found that when they ran the weather simulation over and over with

  • slight variations in input resulting in vastly different results, when you visualize these

  • patterns, the paths never overlapped.

  • But at the same time, the paths seemed to circle these empty areas of spacethis pattern

  • is an example of what’s called a strange attractor and one thing that differentiates

  • a chaotic system from random behavior. With Lorenz’s particular chaotic example, the

  • visualization starts to look a bit like a butterfly.

  • The phraseif a butterfly flaps its wings in Brazil it could cause a hurricane in Texas

  • is not what the theory is named after, it’s just a memorable example.

  • This first chaos work required some innovative computing, and although Lorenz typically gets

  • all the credit for being thefatherof our modern chaos theory, he actually did

  • this work with two young mathematicians, Margaret Hamilton and Ellen Fetter.

  • Hamilton later went on to develop the math that got Apollo 11 to the moon, and is credited

  • with coining the termsoftware engineering’.

  • So many natural systems are chaotic, like the climate as a whole, the dynamics of clouds,

  • population dynamics, the patterns of the stock market...the way your milk swirls into and

  • combines with your coffee?

  • That’s chaos theory in fluid dynamics. These systems may be chaotic and have seemed impossibly

  • daunting in the past.

  • But the math of chaos theory is now small potatoes to the huge supercomputers that we

  • can use to calculate the progression of chaotic systems like the climate with more accuracy

  • than ever before.

  • Even outside of modeling, chaos theory proves exceptionally useful in other fields...like

  • encryption. And as we move into brave new worlds of exascale computing, quantum computing,

  • machine learning and other kinds of artificial intelligence, itll be exciting to see just

  • how far we can push chaos theory to help us predict the behavior of chaotic systems...essentially

  • looking further into the future than we ever have before.

  • If you want more on unusual math, check out our video on fractals over here, and subscribe

  • to Seeker for more deep dives into tangled topics like this.

  • Let us know what math subject you want us to tackle next in the comments below, and

  • as always, thanks for watching.

If someone showed you a swinging pendulumlike this and asked you to calculate the pendulum’s

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カオス理論はいかにして自然の謎を解き明かすか (How Chaos Theory Unravels the Mysteries of Nature)

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    林宜悉 に公開 2021 年 01 月 14 日
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