Definition:Basis Expansion/Positive Real Numbers

Definition
Let $x \in \R$ be a real number such that $x \ge 0$.

Let $b \in \N: b \ge 2$.

Let us define the recursive sequence:
 * $\forall n \in \N: n \ge 1: \left \langle {f_n}\right \rangle = \begin{cases}

b \left({x - \left \lfloor {x} \right \rfloor}\right) & : n = 1 \\ b \left({f_{n-1} - \left \lfloor {f_{n-1}} \right \rfloor}\right) & : n > 1 \end{cases}$

Then we define:
 * $\forall n \in \N: n \ge 1: \left \langle {d_n}\right \rangle = \left \lfloor {f_n} \right \rfloor$

It follows from the method of construction and the definition of the floor function that:


 * $\forall n: 0 \le f_n < b$ and hence $\forall n: 0 \le d_n \le b - 1$
 * $\forall n: f_n = 0 \implies f_{n+1} = 0$ and hence $d_{n+1} = 0$.

Hence we can express $x = \left \lfloor {x} \right \rfloor + \sum_{j \ge 1} \frac {d_j} {b^j}$ as:
 * $\left[{s . d_1 d_2 d_3 \ldots}\right]_b$

where $s = \left \lfloor {x} \right \rfloor$.

This is called the expansion of $x$ in base $b$.

The generic term for such an expansion is a basis expansion.

It follows from the Division Theorem that for a given $b$ and $x$ this expansion is unique.

If it is the case, for a given $x$ and $b$, that $\exists m \in \N: d_m = 0$ then the expansion is said to terminate.

Note that it is far from guaranteed that the sequence $\left \langle {d_n}\right \rangle$ will actually terminate.