===== Integer ===== ==== Set ==== | @#FFBB00: definiendum | @#FFBB00: $ \mathbb Z \equiv \mathbb N\times\mathbb N\ /\ \{\langle \langle a,b\rangle,\langle m,n\rangle\rangle\ |\ a+n = b+m )\} $ | with $a,b,n,m\in \mathbb N$. ==== Discussion ==== For $a \ge b$, we denote $\langle a,b\rangle$ by $a-b$. The structure of the non-negative integers is then that of the natural numbers. For $a < b$, we have $(b-a)>0$ and we denote $\langle a,b\rangle$ by $-(b-a)$. So if $[\langle a,b\rangle]$ is the equivalence class of $\langle a,b\rangle$ with respect to the equivalence relation $\{\langle \langle a,b\rangle,\langle m,n\rangle\rangle\ |\ a+n = b+m )\}$, we have * $ 0 \equiv [\langle0,0\rangle] = [\langle1,1\rangle] = \dots = [\langle k,k\rangle] $ * $ 1 \equiv [\langle1,0\rangle] = [\langle2,1\rangle] = \dots = [\langle k+1,k\rangle] $ * $ -1 \equiv [\langle0,1\rangle] = [\langle1,2\rangle] = \dots = [\langle k,k+1\rangle] $ * $ 2 \equiv [\langle2,0\rangle] = [\langle3,1\rangle] = \dots = [\langle k+2,k\rangle] $ * $ -2 \equiv [\langle0,2\rangle] = [\langle1,3\rangle] = \dots = [\langle k,k+2\rangle] $ * $ 3 \equiv [\langle0,3\rangle] = \dots $ where $k$ is any natural number. === Theorems === The integer $-[\langle a,b\rangle]$ is the additive inverse of $[\langle a,b\rangle]$ and can be computed as $-[\langle a,b\rangle]=[\langle b,a\rangle]$ === Reference === Wikipedia: [[http://en.wikipedia.org/wiki/Integer|Integer]] ==== Parents ==== === Subset of === [[Quotient set]] === Refinement of === [[Rational number]] === Context === [[Arithmetic structure of natural numbers]]