P-adic number

In number theory, given a prime number $p$ , the $p$ -adic numbers form an extension of the rational numbers which is distinct from the real numbers, though with some similar properties; $p$ -adic numbers can be written in a form similar to (possibly infinite) decimals, but with digits based on a prime number $p$ rather than ten, and extending to the left rather than to the right.

For example, comparing the expansion of the rational number ${\tfrac {1}{5}}$ in base $3$ vs. the $3$ -adic expansion,

{\begin{alignedat}{3}{\tfrac {1}{5}}&{}=0.01210121\ldots \ ({\text{base }}3)&&{}=0\cdot 3^{0}+0\cdot 3^{-1}+1\cdot 3^{-2}+2\cdot 3^{-3}+\cdots \\[5mu]{\tfrac {1}{5}}&{}=\dots 121012102\ \ ({\text{3-adic}})&&{}=\cdots +2\cdot 3^{3}+1\cdot 3^{2}+0\cdot 3^{1}+2\cdot 3^{0}.\end{alignedat}}

Formally, given a prime number $p$ , a $p$ -adic number can be defined as a series

s=\sum _{i=k}^{\infty }a_{i}p^{i}=a_{k}p^{k}+a_{k+1}p^{k+1}+a_{k+2}p^{k+2}+\cdots

where $k$ is an integer (possibly negative), and each $a_{i}$ is an integer such that $0\leq a_{i}<p.$ A $p$ -adic integer is a $p$ -adic number such that $k\geq 0.$

In general the series that represents a $p$ -adic number is not convergent in the usual sense, but it is convergent for the $p$ -adic absolute value $|s|_{p}=p^{-k},$ where $k$ is the least integer $i$ such that $a_{i}\neq 0$ (if all $a_{i}$ are zero, one has the zero $p$ -adic number, which has $0$ as its $p$ -adic absolute value).

Every rational number can be uniquely expressed as the sum of a series as above, with respect to the $p$ -adic absolute value. This allows considering rational numbers as special $p$ -adic numbers, and alternatively defining the $p$ -adic numbers as the completion of the rational numbers for the $p$ -adic absolute value, exactly as the real numbers are the completion of the rational numbers for the usual absolute value.

$p$ -adic numbers were first described by Kurt Hensel in 1897,^[1] though, with hindsight, some of Ernst Kummer's earlier work can be interpreted as implicitly using $p$ -adic numbers.^{[note 1]}

^ (Hensel 1897)

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[1] (Hensel 1897)

[1]

[note 1]