Originally posted by BlasterBates
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ok ok I'll rephrase it
R is the set of real numbers
so what we are proving is the following
The set X = {x:R | x > 0}
for all x1, x2 in X the following is true x1 + x2 > 0Leave a comment:
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My A-level maths is not good enough to follow some of these arguments.
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The statement is not part of the axioms, so it must be proved. The proof is trivial but so is the proof to the original question.Originally posted by Euro-commuterImplicit in the definitions of unity and inverse, no?
What you prove on the way, and what is taken as obvious, has always intrigued me. Technically, all of mathematics is tautologically implicit in the axioms. A "proof" is an exposition of the steps in detail small enough for mathematicians to follow, and preferably too great for others to follow
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x > 0 => x + (-x) > 0 + (-x) => 0 > -x QED
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Implicit in the definitions of unity and inverse, no?Originally posted by bored
What you prove on the way, and what is taken as obvious, has always intrigued me. Technically, all of mathematics is tautologically implicit in the axioms. A "proof" is an exposition of the steps in detail small enough for mathematicians to follow, and preferably too great for others to follow.
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Your proof indeed almost derives from the axioms - you haven't proved that if x>0, then -x<0.Originally posted by Euro-commuter
A simple proof that starts from the axioms would be like this:
a) x > 0 => x + y > 0 + y = y
b) x + y > y, y > 0 => x + y > 0Leave a comment:
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Assuming x and y are real numbers, it follows from the fact that the set of real numbers is an ordered fieldOriginally posted by BlasterBates
As someone else mentioned (I forget who), x > 0 implies x + y > y for any real y (not necessarily positive).
Also by the transitive property of a strict total order if z > y and y > t then z > t, where in particular you can take z = x + y and t = 0.Leave a comment:
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I assumed a strict total order, i.e. asymmetric and transitive. But it does indeed have to be at least a group. Surely though the proof for a strictly stronger space like a ring or a field would be just the same as for a group? Only the basic group properties are being used here. (note to the less technical: what I mean by that is that a proof relating to addition and subtraction is just the same whether you are able to do multiplication or not).Originally posted by boredLast edited by Euro-commuter; 31 July 2007, 20:26.Leave a comment:
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Ah yes, the axioms!!! I was going to say that!!Originally posted by bored
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The exact proof depends on what axioms you assume for the "<" ordering. Say the proof will be different if you start with the axioms of an ordered group or an ordered field.Leave a comment:
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Assume the opposite is true, i.e. there exist x and y such thatOriginally posted by BlasterBates
x > 0
y > 0
x+y <= 0.
then x+y-y <= 0-y
i.e. x <= -y
but y > 0 so -y < 0
therefore x < 0 which contradicts first premise.
Therefore the assumption is false, so there do not exist x any y such that
x > 0
y > 0
x+y <= 0.
Therefore x+y > 0.
PS just how many of us claimed to have a maths degree??Leave a comment:
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