Quotient and Remainder to Number Base

Theorem
Let $n \in \Z: n > 0$ be an integer.

Let $n$ be expressed in base $b$:
 * $\displaystyle n = \sum_{j \mathop = 0}^m {r_j b^j}$

i.e.
 * $n = \left[{r_m r_{m-1} \ldots r_2 r_1 r_0}\right]_b$

Then: where:
 * $\displaystyle \left \lfloor {\frac n b} \right \rfloor = \left[{r_m r_{m-1} \ldots r_2 r_1}\right]_b$
 * $n \,\bmod\, b = r_0$
 * $\left \lfloor {.} \right \rfloor$ denotes the floor function;
 * $n \,\bmod\, b$ denotes the modulo operation.

General Result

 * $\displaystyle \left \lfloor {\frac n {b^s}} \right \rfloor = \left[{r_m r_{m-1} \ldots r_{s+1} r_s}\right]_b$
 * $\displaystyle n \,\bmod\, {b^s} = \sum_{j = 0}^{s-1} {r_j b^j} = \left[{r_{s-1} r_{s-2} \ldots r_1 r_0}\right]_b$

where $s \in \Z: 0 \le s \le m$.

Proof
From the Quotient-Remainder Theorem, we have:


 * $\exists q, r \in \Z: n = q b + r$

where $0 \le b < r$.

We have that:

Hence we can express $n = q b + r$ where:
 * $\displaystyle q = \sum_{j \mathop = 1}^m {r_{j} b^{j-1}}$
 * $r = r_0$

where:
 * $\displaystyle \sum_{j \mathop = 1}^m {r_j b^{j-1}} = \left[{r_m r_{m-1} \ldots r_2 r_1}\right]_b$

The result follows from the definition of the modulo operation.

Proof of General Result
Follows directly by induction on $s$.

Example
This result is often used in computer algorithms for converting a date (in $yyyymmdd$ format) into a date object with separate day, month and year.

Performing the above "mod and div" operations on $20100209$, we get: