Sunday 23 November 2014

Mathematical!

At the beginning of this year I was sitting at work, waiting for the hours to tick by, when I began to wonder what I would do if I discovered I was immortal. Many scientists have believed for some time that the first person to live to be 200 has already been born, so it may not even be as impossible a situation as it sounds. I figured the key thing for an immortal would be capitalising on long-term investment. Money is certainly a nice thing to have a lot of, but surely the novelty would soon wear off and the eons of malaise would set in.
I would need a good hobby to stay occupied throughout the millennia, so I figured I would learn everything. Take every course under the sun and become a specialist in every field. The more I thought about it, the more it made sense, and then another though occurred. What if I set out on this quest for ultimate smarts and then, only later, discovered I was not immortal? Then I would have spent a lifetime of optimistic work, chasing a dream. Life is probably longer than it seems, so why not live like it’s endless?

I decided to go back to uni and study something new. As I have a degree in visual-arts, I thought I’d go the other way and begin again in science.

Maths was an interesting option. I’d liked maths as a kid, but by high school it had started to seem like an endless chore. Maybe there was more to it. And as an immortal I could afford to give it another look.

Unfortunately maths at ANU is not exactly child’s-play. Taking an English class is not easy, but if you don’t speak the language it’s practically impossible. Having not studied tertiary maths I did not speak the language, and the serious courses required a double-major in college maths. Also, I happened to be considering all of this just two weeks before the beginning of classes.

I submitted a very late application for a bachelor of science at ANU and turned to the internet to see if it was possible to learn maths in a fortnight.

Fortunately, Khan Academy.
That guy will learn you brains you didn’t know what were.

I spent about 10-12 hours a day working through the courses. My application for uni was successful and I signed up for maths. The first thing the course provided was a general test designed to outline what you should know. I passed, and the course began. I also took psychology, biology and physics. The first two were simple enough because they didn’t require a lot of pre-knowledge, but physics needed both maths and physics experience. The courses started at the beginning anyway, but maths and physics took off at a blistering pace. I had to work harder than I’ve ever worked on anything, but I kept up. I never really got ahead of the curve in physics but maths started to fall into place, and I wound up getting a HD.

For the first time I saw math teachers who actually cared about maths, and I started to get a glimpse of the depth of the subject. The biggest change, though, came from reading Paul Lockhart’s book, which shows the fundamentally aesthetic nature of maths, and how poorly this tends to be communicated in school.

I’m definitely hooked on this approach now, and I thought I’d attempt to explain through a problem that I came up with myself.

Introducing; Simon’s Marvellous Math Problem of Fantastical Wonder.

The problem follows as such:
If you take two standard A4 sheets of paper, and put them next to each other with the short sides at the top, this makes an A3 sheet of paper. The interesting thing about this is, the A3 sheet is the same shape as the A4, just a scaled up version.  So the question is: What’s the deal with that?



The first thing to notice is that there can only be one particular rectangle that has this property. Two squares next to each other make a rectangle, and vice versa. So at some specific point in between a 1x1 square and a 1x2 rectangle there is a magic shape that is half of itself.



The easiest way to describe a rectangle is by the two lengths of the sides, but in our case, it doesn’t matter what the size of the rectangle is, only the shape. So the thing we’re looking for, the thing that doesn’t change with the scale of the shape, is the ratio of the sides.

A 1x2 rectangle is the same shape as a 2x4 rectangle because ½ = 2/4 = 0.5



So how do we find the ratio of the sides of an A4 sheet?

We could try looking up the measurements.
International A4 size is 210 x 297mm. So the ratio of the short side to the long side is 210/297 or  0.70707070707(repeating).

That’s cool, but what about an A3 sheet. It should be the same ratio, right?
International A3 size is 297 x 420mm. So the ratio is 297/420 or 0.70714285714...

What we’ve discovered is that the shape of A4 paper is very close to having the property we described, but not perfect, because 0.70707070707 is not exactly the same as 0.70714285714. So is it possible to have a perfect ratio, and what is it, and why?!?

The first clue to working it out is that both the A4 and A3 sheets share a measurement: 297mm. This is because the long side of the A4 becomes the short side of the A3.



Knowing this we can do something tricky. If we arbitrarily decide that the short side of the A4 is 1 unit in length (it doesn’t matter what the unit is; 1cm or 1billion cm), then the long side is the unknown length, which we’ll call Z. And by studying the picture below we can see something interesting:



If the A4 shape is 1/Z, then the A3 shape can also be described using those units.  It’s short side is Z, and it’s long side is the same as 2 A4 short sides, which makes it’s ratio Z/2.

For the shapes to be the same, the ratios of the lengths must be identical, which means:



The question has become; “what number must Z be to make this statement true?”
To find this, we can alter the way we express this statement, and “solve for Z”

Because the A3 side is “Z divided by two”, if we double everything this comes out as



Did we get anywhere? Now Z equals two divided by Z. To get rid of the fraction we can do the same thing again, except this time we multiply everything by Z.



Now there’s only one Z in the equation but it’s squared.  That’s not a problem though, if 2 equals Z x Z, then that just means Z is a number that if you multiply it by itself you get 2. Which we can express as



Now we have it. It turns out that the only ratio of lengths that our perfect A4 rectangle can have is



So what is the square root of two?

1 * 1 = 1
1.5 * 1.5 = 2.25
So it must be between those two numbers. If we type it into a calculator it comes out as 1.41421356237. Fair enough. Is that the end of the story?
But what if we calculate 1.41421356237 * 1.41421356237?
This comes out as 1.99999999999.

So this can’t really be the square root of 2. The calculator must have not given us the precise value because it can only display a limited amount of numerals after the decimal point. So how many numerals would be required for the precise value that is equal to the square root of two?

The answer is infinite.

Just like the value pi, which is the ratio of a circle’s circumference to it's diameter, the value equal to the square root of two cannot be described with numerals. This type of number is called “irrational”.



Pythagoras and the some other ancient Greek lads discovered this and came up with a proof by showing that the number could not be even, but also could not be odd. Pythagoras actually tried to hide this fact because his troop had developed a kind of number-based religion that stated that all values could be expressed as fractions.

Much later down the track, a mathematician discovered that there are actually more irrational numbers than rational ones. In fact there are so many more irrational numbers that if you threw a dart at a number-line, and with infinite care, found the exact value that the dart hit, the chance of this value being a rational number (1 or 2 or ½ or 118739182/19723649872634 etc.)
Is actually zero!

So we have answered the question of what the perfect A4 shape is, but we haven’t really worked out why this is.

There is, of course, no complete answer to this question, but still, we might be able to find some interesting clues.

One interesting thing to note is that if you have a square with sides of length 1, the length of the diagonal is also the square root of two (which is essentially where we get the term “square root”)



This doesn’t seem like an accident. There must be some intrinsic connection between the two questions “How long is the diagonal in a square?” and “How long is longer side of a shape that is equal to half of itself?”

Now, we are in the domain of mathematics. This is what maths is about. Maths doesn’t care what the ratio of two lengths are, it cares about why that ratio is the way it is.
In school we’re taught algebra and the like as though calculation is the purpose of maths. This couldn’t be more wrong. Discovering the intrinsic nature of the realms of our thoughts is what maths is about.
But the thing is, knowing a bit of algebra enabled us to go from a question about the shape of an A4 page to a deeper question about the connection between two shapes and an irrational number. Without algebra and other concepts, that journey, and the journey on from there into more interesting questions, would be essentially impossible.

The tools of maths need to be learnt in order to ask the interesting questions, but too many maths teachers have forgotten or have never learnt that the tools are the means to studying maths, not the subject itself.

As to the question of the connection between our shape and the diagonal of a square, if you have read this far you’ve proven yourself able to take up this question yourself. But I’ll share two things that I discovered from various ponderisations.

First, if you take a square with sides of root 2, the diagonal is of length 2.




And, second, when you go from an A4 to an A3 size, the area doubles. Similarly the area of a square doubles when the side length becomes the diagonal length.


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