User:Grover cleveland/Real numbers

Proposed replacement for definition of Dedekind cuts

A Dedekind cut in an ordered field is a partition of it, (A, B), such that A is nonempty and closed downwards, B is nonempty and closed upwards, and A contains no greatest element. Real numbers can be constructed as Dedekind cuts of rational numbers.

For convenience we may take the lower set ${\displaystyle A}$  as the representative of any given Dedekind cut ${\displaystyle (A,B)}$ , since ${\displaystyle A}$  completely determines ${\displaystyle B}$ . By doing this we may think intuitively of a real number as being represented by the set of all smaller rational numbers. In more detail, a real number ${\displaystyle r}$  is any subset of the set ${\displaystyle {\textbf {Q}}}$  of rational numbers that fulfils the following conditions:

1. ${\displaystyle r}$  is not empty
2. ${\displaystyle r\neq {\textbf {Q}}}$ 
3. r is closed downwards. In other words, for all ${\displaystyle x,y\in {\textbf {Q}}}$  such that ${\displaystyle x<y}$ , if ${\displaystyle y\in r}$  then ${\displaystyle x\in r}$ 
4. r contains no greatest element. In other words, there is no ${\displaystyle x\in r}$  such that for all ${\displaystyle y\in r}$ , ${\displaystyle y\leq x}$ 

• We define a total ordering on the set ${\displaystyle {\textbf {R}}}$  of real numbers as follows: ${\displaystyle x<y\Leftrightarrow x\subset y}$ 

• We embed the rational numbers into the reals by identifying the rational number q with the set of all smaller rational numbers ${\displaystyle \{x\in {\textbf {Q}}:x<q\}}$ . Since the rational numbers are dense, such a set can have no greatest element and thus fulfils the conditions for being a real number laid out above.

• Addition. ${\displaystyle A+B:=\{a+b:a\in A\land b\in B\}}$ 

• Subtraction. ${\displaystyle A-B:=\{a-b:a\in A\land b\notin B\}}$ 

• Negation is a special case of subtraction: ${\displaystyle -B:=\{a-b:a<0\land b\notin B\}}$ 

• Defining multiplication is less straightforward.
  • if ${\displaystyle A,B\geq 0}$  then ${\displaystyle A\times B:=\{a\times b:a\geq 0\in A\land b\geq 0\land b\in B\}\cup \{x:x<0\}}$ 
  • if either ${\displaystyle A}$  or ${\displaystyle B}$  is negative, we use the identities ${\displaystyle A\times B=-(A\times -B)=-(-A\times B)}$  to convert ${\displaystyle A}$  and/or ${\displaystyle B}$  to nonnegative numbers and then apply the definition above.
• We define division in a similar manner:
  • if ${\displaystyle B>0}$  then ${\displaystyle A/B:=\{a/b:a\in A\land b\notin B\}}$ 
  • If ${\displaystyle B}$  is negative, we use the identity ${\displaystyle A/B=-(A/-B)}$  to convert ${\displaystyle B}$  to a positive number and then apply the definition above.

We may further define exponentiation. First define functions Num(q) and Den(q), where q is rational as being the numerator and denominator respectively of q expressed in lowest terms with a positive denominator:

• • if ${\displaystyle A>0}$ , then ${\displaystyle A^{B}:=\{x\in \mathrm {Q} :\exists a\in A\exists b\in B((a\geq 0\land x^{Dem(b)}<a^{Num(b)}))\}}$