Things tend to get wonky when we start throwing infinity around.
I always found it weird 1 - .999 repeating = 0.
Or that there are the same number of even numbers as there are integers. Seems like there would be twice as many integers. Not so, apparently. Something to do with 1 to 1 correlation, or matrices or whatever. Who knows really (aside from math people).
The point being, if I say there are less even numbers from 1 to 100 than integers , I'm correct. (50 < 100). And that works for any number. But it doesn't work for infinity, because as I said, things get wonky at infinity.
So when you take a nice happy idea like a normal chain of effect, and then make it infinite and stick it in the context of a space/time that we don't understand, and assume that it's not any different than a normal chain of effect, you've probably got a suspect premise.
I always found it weird 1 - .999 repeating = 0.
Or that there are the same number of even numbers as there are integers. Seems like there would be twice as many integers. Not so, apparently. Something to do with 1 to 1 correlation, or matrices or whatever. Who knows really (aside from math people).
The point being, if I say there are less even numbers from 1 to 100 than integers , I'm correct. (50 < 100). And that works for any number. But it doesn't work for infinity, because as I said, things get wonky at infinity.
So when you take a nice happy idea like a normal chain of effect, and then make it infinite and stick it in the context of a space/time that we don't understand, and assume that it's not any different than a normal chain of effect, you've probably got a suspect premise.
