Real number: Difference between revisions

Latest revision as of 18:52, 8 July 2024

I am not yet sure how to define real numbers. Many irrational numbers (e.g. ${\sqrt {2}}$ and $\pi$ ) are in fact valid concepts, but the standard definition of the reals involves infinite nonsense.

The concept of real numbers is a concept: it identifies things out in reality. In particular, it does not need to be "constructed" via some set-theoretic method like Dedekind cuts, nor do such constructions even make sense. That any real number can be approximated by fractions is obvious: a fraction is the outcome of directly measuring any quantity with a standard ruler.

A real number should really just be the concept of a number, meant in the broadest sense. Strictly speaking, quaternions, complex numbers, elements of finite fields, etc. are not numbers.

Examples

Any fraction.

Some algebraic numbers, like ${\sqrt {2}}$ .

Pi

e

The number $0.x_{1}x_{2}x_{3}x_{4}\cdots$ , where $x_{i}:\{0,1\}$ is its $i$ th digit in base 2, and where $x_{i}=1$ if $i$ is prime, and 0 otherwise. [TODO wtf does that mean]

The Euler-Mascheroni constant (where we don't actually know for sure whether or not it is rational) [TODO I'm not sure if it really makes sense]

@@ Line 8: / Line 8: @@
 Any [[fraction]].
-Any [[Radical|algebraic number]], like <math>\sqrt{2}</math>.
+Some [[Radical|algebraic numbers]], like <math>\sqrt{2}</math>.
 [[Pi]]
 [[e]]
 The number <math>0.x_1 x_2 x_3 x_4 \cdots</math>, where <math>x_i : \{0,1\}</math> is its <math>i</math>th digit in base 2, and where <math>x_i = 1</math> if <math>i</math> is prime, and 0 otherwise. [TODO wtf does that mean]
 The Euler-Mascheroni constant (where we don't actually know for sure whether or not it is rational) [TODO I'm not sure if it really makes sense]

Real number: Difference between revisions

Latest revision as of 18:52, 8 July 2024

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