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From: Archimedes Plutonium on 19 Jul 2010 03:26 It turns out that a precision definition of finite-number versus infinite-number had two severe cases in all of mathematics, one in Algebra as the Fermat's Last Theorem and the other in geometry as the Poincare Conjecture. Until recently I would have thought that the Riemann Hypothesis RH was unprovable because it was another victim of this non definition of what it means to be a finite-number. But as it turns out, RH only needed a clever mind, the same said for Twin Primes, Perfect Numbers conjectures and Goldbach. So the most severe case of having to define finite-number was FLT in Algebra and the Poincare Conjecture. And one can sympathize with why geometry seems to glide along without knowing the titantic iceberg of defining the boundary of infinity. Not too many people really think about infinity of the small as you approach the number 0 from 1 or the number 1 approached from 2. Not too many people in mathematics ever question "absolute continuity". Only perhaps a tiny few of all people that ever lived asked whether the axioms of geometry are compatible, consistent with infinity on the small scale. So it is rather easy and understandable that no problems would ever come up that directly question absolute-continuity, except of course the Poincare Conjecture. And obviously there would be no proof because internally it is false. Now there has been some brouhaha recently of claims of an alledged proof, but those are fakery-proofs. And it is rather surprizing that the Calculus which is centered on the small with its concept of limit, surprizing that it seems to have glided past the awful omission of a definition of finite versus infinite boundary. But the Calculus has not really escaped unscathed by the omission. For it is not long when someone earnestly studies Calculus that you get into so much thorny questions of continuity. So I think the Calculus was never at ease with continuity, and was fighting every day since the birth of Calculus. Does the 10^-500 lower bound help Calculus? I happen to think it strengthens the Calculus, in that when you reach 10^-500 and want to talk about smaller, you simply say the same as dividing by zero, that it is "undefined". And that leaves only FLT and Poincare Conjectures as the most severe victims of never a precision definition of finite-number versus infinite-number. It seems to me, that math ducked the issues rather well without a precision definition. One would think math of today, having never defined the boundary should be in a whole lot worse shape. Perhaps it is in bad shape but that we are so climatized in our own era, that only future generations can look back and claim "how the 19th, 20th centuries were such Dark Ages of mathematics". We have two new geometries of NonEuclidean geometries of which we have only begun to scratch the surface of this new subject, and perhaps that is largely due to how much time we waste on nonmath subjects of NP, 4 Color Mapping, Poincare Conjecture, FLT, the Cantor issue. But a whole bunch of other time wasters such as the transcendental number theory. So this precision definition of finite number is a full sweeping cleaning up and cleaning out of mathematics, and it sorely needs it. It is worth noting and repeating, that the infinity defined without a boundary and due to quantum duality logic, that mathematics is destroyed by such an infinity, and it makes Cantor's infinities look like some harmless silly toy infinity. So it is not a matter of "if" math defines the boundary, but when, and that I am only the one that started the process moving forward. Math is, afterall, the science of precision and it is its duty, its job to precision define. Archimedes Plutonium http://www.iw.net/~a_plutonium/ whole entire Universe is just one big atom where dots of the electron-dot-cloud are galaxies |