Читаем Using Your Brain —for a CHANGE полностью

At this point, how long do you think you could remember this number accurately? — an hour? — a day? — a week?

Now let's chunk the number a little differently. Does this suggest anything to you?

1 4 9 16 25 36 49 64 81 100

We can write this same set of numbers a little differently, as squares of numbers:1²2²3²4²5²6²7²8²9²10²

Now it's obvious that the number we started with is the squares of the numbers 1 through 10, strung together. Knowing this, you can easily remember this number ten or twenty years from now. What makes it so easy? You have much less to remember, and it's all coded in terms of things that you have already remembered. This is what math and science is all about — coding the world efficiently and elegantly, so that you have fewer things to remember, leaving your brain free to do other things that are more fun and interesting.

Those are just a few of the principles that can make remembering a lot easier and faster. Unfortunately they're not yet used much in mainstream education.

One of the nice things that happens after you write enough books is that people let you do things that you wanted to do before, but couldn't. Typically by that time you can't quite remember what they were, but I had written some of them down. When I was asked to work for a school district, I had a few things I wanted to go after. One of them is the whole notion of "learning disabilities," "minimal brain dysfunction," "dyslexia," or "educational handicaps." Those are very important – sounding words, but what they all describe is that the teaching isn't working.

Whenever a kid isn't learning, experts are quick to conclude that the problem is a "learning disability," ... but they're never quite clear about who has it! Perhaps you've noticed that they never call it a "teaching disability." The implication is always that the cause of the failure is that the kid's brain is weak or damaged, often by presumed genetic causes. When people don't know how to change something, they often start searching for a way to justify failure, rather than thinking about how they could try doing something different to make it work. If you assume that a kid has a limp learning lobe, then there's nothing you can do about it until they perfect brain grafts.

I'd rather not explain failure that way. I'd rather think about it as a "teaching dysfunction," and at least leave open the possibility that we can learn to change it. If we pretend that you can teach anyone anything, we'll find out where it's not (yet) true. But if we think that when someone isn't learning it means they can't be taught, no one will even try.

In the last century it was common knowledge that man couldn't fly. Then when airplanes became a part of everyday life, most people didn't think it was possible to put a man on the moon. If you take the attitude that anything is possible, you'll find that a lot of things that were previously thought impossible actually do become possible.

The whole idea of "learning disabilities" is based primarily on old neurological "ablation" studies that resulted from a fairly primitive idea of how the brain works: that you can figure out what something does by noticing what happens when it's broken. They would find damage in one part of the brain of someone who couldn't talk, and say, "That's where speech is." That is the same logic as cutting a wire in a television set, noticing that the picture tilts, and saying, "That wire is where the picture straightness is." There are thousands of wires, connections, and transistors involved in holding the picture straight, in a very complex and interdependent system, and the brain is a lot more complex than a TV set. For some of the more primitive areas of the brain there actually is a certain degree of localization of function. However, it's also been known for years that a young child can lose an entire cerebral hemisphere and learn everything all over again perfectly on the other side.

Recent evidence is throwing out a lot of old neurological dogma. In an X–Ray Tomography study they found a college graduate with an 10 of 120 who had such enlarged brain ventricles that his cortex was only about a centimeter thick! Most of his skull was filled with fluid, and according to dogma, he shouldn't have been able to get up in the morning, let alone go to college!

Another old dogma is that in vertebrates no new neurons are formed after birth. Last year they found that the number of neurons in the part of a male canary's brain devoted to singing doubles each spring, and then half of them die off during the rest of the year.