The Physics of Wall Street: a brief History of Predicting the Unpredictable
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From Coastlines to Cotton Prices
• 59 pointed out that this wasn’t quite right; really, you expect the prices to change by some fixed percentage each time God flips his coin, rather than some fixed amount. this modification led to the observations that rates of return should be normally distributed and prices should be log-normally distributed. the normal distribution shows up in all sorts of places in nature. If you took the heights of all of the men in a given part of the world and plotted how many of them were 5 feet 6 inches, how many 5 feet 7 inches, and so on, you would get a normal distribution. If you used a thousand thermometers and tried to take your temperature with each of them, the results would look like a normal distribution. If you played a coin-flipping game in which you got a dollar every time the coin landed heads, and you lost a dollar every time it landed tails, the probabilities governing your profits after many plays would look like a normal distribution. this is convenient: normal distributions are easy to understand and to work with. for instance, if something is normally distributed and your sample is large enough, the sample’s average value tends to converge to a particular number; white men, on average, are about 5 feet 9 inches, and unless you are ill, the thousand thermometers’ readings will average 98.6 degrees fahrenheit. Your av- erage profits in the coin-tossing game will converge to zero. this rule can be thought of as the law of large numbers for prob- ability distributions — a generalization of the principle discovered by Bernoulli, linking probabilities to the long-run frequencies with which events occur. It says that if something is governed by certain probability distributions, as men’s heights are governed by a normal distribution, then once you have a large enough sample, new instances aren’t going to affect the average value very much. once you have mea- sured many men’s heights in a given region of the world, measuring one more man won’t change the average height by much. not all probability distributions satisfy the law of large numbers, however. the location of the drunken vacationer in cancun does — he is taking a random walk, so on average, he will stay right where he started, just as the average profits from a coin-tossing game converge to zero. But what if instead of a drunk trying to walk to his hotel, you had a drunken firing squad? each member stands, rifle in hand, facing a wall. (for argument’s sake, assume the wall is infinitely long.) Just like the drunk walking, the drunks on the firing squad are equally li- able to stumble one way as another. When each one steadies himself to shoot the rifle, he could be pointing in any direction at all. the bullet might hit the wall directly in front of him, or it might hit the wall 100 feet to his right (or it might go off in the entirely opposite direction, missing the wall completely). Suppose the group engages in target practice, firing a few thousand shots. If you make a note of where each bullet hits the wall (counting only the ones that hit), you can use this information to come up with a distribution that corresponds to the probability that any given bullet will hit any given part of the wall. When you compare this distribu- tion to the plain old normal distribution, you’ll notice that it’s quite different. the drunken firing squad’s bullets hit the middle part of the wall most of the time — more often, in fact, than the normal distribu- tion would have predicted. But the bullets also hit very distant parts of the wall surprisingly often — much, much more often than the normal distribution would have predicted. this probability distribution is called a cauchy distribution. Be- cause the left and right sides of the distribution don’t go to zero as quickly as in a normal distribution (because bullets hit distant parts of the wall quite often), a cauchy distribution is said to have “fat tails.” (You can see what the cauchy distribution looks like in figure 3.) one of the most striking features of the cauchy distribution is that it doesn’t obey the law of large numbers: the average location of the fir- ing squad’s bullets never converges to any fixed number. If your firing squad has fired a thousand times, you can take all of the places their bullets hit and come up with an average value — just as you can aver- age your winnings if you’re playing the coin-flip game. But this average value is highly unstable. It’s possible for one of the squad members to get so turned around that when he fires next, the bullet goes almost parallel with the wall. It could travel a hundred miles (these are very powerful guns) — far enough, in fact, that when you add this newest result to the others, the average is totally different from what it was be- fore. Because of the distribution’s fat tails, even the long-term average location of a drunken firing squad’s bullets is unpredictable. 60 • t h e p h y s i c s o f wa l l s t r e e t From Coastlines to Cotton Prices • 61 As Mandelbrot described it, the war, especially during the first two years under vichy rule, left huge swaths of france unaffected for long periods. But then “a storm” would come through and wreak havoc, followed by another period of calm. So perhaps it is no surprise that Mandelbrot was fascinated by these bursts, by random processes that couldn’t be tamed like a casino game. He called events that obeyed a cauchy distribution wildly random, to distinguish them from the plain, mild randomness of the random walk, and he devoted much of his career to studying them. When Mandelbrot began his career, most statisticians assumed that the world is filled with normally distributed figure 3: the location of a drunken vacationer trying to find his hotel room on a long corridor is governed by a normal distribution. But not all random processes are governed by normal distributions. Where the bullets fired by a drunken firing squad will land is determined by a different sort of distribution, called a cauchy distribution. (note that the angle at which the members of the drunken firing squad fire will be governed by a normal distribution; it’s the location on the wall that they are trying to hit that is governed by the cauchy distribution!) cauchy distributions (the solid line in this figure) are thinner and taller than normal distributions (the dashed line) around their central values, but their tails drop off more slowly — which means that events far from the center of the distribution are more likely than a normal distribution would predict. for this reason, cauchy distributions are called “fat-tailed” distributions. Mandelbrot called phenomena governed by fat-tailed distributions “wildly random” because they experience many more extreme events. events; though cauchy and other fat-tailed distributions might show up sometimes, they were believed to be the exception. More than any- one else, Mandelbrot showed just how many of these so-called excep- tions there are. think back to the coastline of Britain. Suppose you want to figure out the average size of a promontory, or any outcropping of land. You might start by looking at boulders and jetties, things of a manageable size. You take the average size of all of these. But you aren’t done, be- cause you realize that these jetties and outcroppings are themselves Download 3.76 Kb. Do'stlaringiz bilan baham: 
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