Join Date: Apr 2004
Suppose that, somewhere in New Jersey, there is a hotel with an infinite number of rooms. You arrive late one night and ask the front desk clerk if they have a vacancy. He replies that every room is occupied, however, he can arrange for you to get one. But how, you wonder, if there is no vacancy? The answer is simple: the clerk will simply ask the people in room 1 to move to room 2, those in room 2 to move to room 3, those in 3 to move to room 4, and so on. Since there is an infinite number of rooms, everyone will have a room to move into, and room 1 will be available for you.
Hotel Infinity is an amazing place, you think to yourself as you sign in. But just as the clerk is about to give you your key, an infinite number of people arrive for an APA convention. The clerk cleverly figured out how to get you a room, but can he accommodate an additional infinity of guests? Amazingly, he can. He just asks everyone to move again, but this time to the room number that is twice the number of their current room. In other words, you would move to room 2, the people in 2 would move to 4, those in 3 to 6, those in 4 to 8, and so on. This will leave all odd numbered rooms — an infinite number of them — vacant.
This paradox illustrates an unusual property of infinite sets. With finite sets, a (proper) subset will always contain fewer members than the entire set. A part is smaller than the whole. But with infinite sets that is not the case: one part of the set can be just as large as the whole. For example, there are as many even numbers as there are natural numbers, even though the natural numbers contain all the even numbers plus the odd ones as well. This can be seen by pairing the natural numbers with the even numbers to show that there is a one-to-one correspondence between the two sets:
1 2 3 4 5 6 ...
| | | | | |
2 4 6 8 10 12 ...
Likewise, even though only some numbers are perfect squares (1, 4, 9, 16, 25, ...), and the distance between each perfect square becomes greater and greater as we progress down the number line, there are as many perfect squares as there are natural numbers. For each natural number is the square root of exactly one perfect square. (This is sometimes known as Galileo's Paradox, as it was first pointed out by the famous Italian physicist and astronomer.)
A variation on hotel infinity results in an interesting Zeno-style paradox. Contrary to what might first be supposed, the hotel doesn't have to occupy an infinite space. Suppose the hotel has one room per story. If each room is half the height of the one below, then the entire structure will be only as tall as a two-story building. But if that's the case, then it should have a roof on top. And if it has a roof, then, as any reputable architect can point out, the other side of it ought to be the ceiling over some room. However, what room will that be, given that the hotel has an infinite number of them and therefore no top story?
The Infinite Circle
Nicholas of Cusa (1401-1464) made the following interesting point regarding the shape of an infinite circle. The curvature of a circle's circumference decreases as the size of the circle increases. For example, the curvature of the earth's surface is so negligible that it appears flat. The limit of decrease in curvature is a straight line.
An infinite circle is therefore... a straight line!
Arrow in flight
An arrow in flight is really at rest. For at every point in its flight, the arrow must occupy a length of space exactly equal to its own length. After all, it cannot occupy a greater length, nor a lesser one. But the arrow cannot move within this length it occupies. It would need extra space in which to move, and it of course has none. So at every point in its flight, the arrow is at rest. And if it is at rest at every moment in its flight, then it follows that it is at rest during the entire flight.