Modular Arithmetic

Authors: A~Z, perhaps someone else but not yet (or they've decided to remain hidden like a ninja)

Introduction

Thinking not over the integers as a whole but modulo some integer $n$ instead can prove quite useful in a number of situation. This chapter attempts to introduce to you the basic concepts of working in such a context.

Congruences

For the following chapter, we will assume $n$ is a natural integer, and $a$ and $b$ are two integers. We say that $a$ and $b$ are congruent modulo $n$ when $n\mid (b-a)$ , or equivalently when there is an integer $k$ such that $a=b+kn$ . We denote this by $a\equiv b~ [n]$ or $a \equiv b\mod n$ . I will use the first notation throughout this chapter.

Remark: When $b\neq0$ , we have $a\equiv r~[b]$ , where $r$ is the remainder in the euclidean division of $a$ by

This relation has a number of useful properties:

$\forall c\in \mathbb Z, a\equiv b~[n] \implies ac \equiv bc ~ [n]$
$\forall c \in \mathbb Z, a\equiv b~[n] \implies a+c\equiv b+c ~[n]$
$\forall c \in \mathbb Z, a \equiv b ~[n] \text{ and } b\equiv c~[n]\implies a\equiv c ~[n]$
$\forall m \in \mathbb N, a\equiv b~[n] \implies a^m\equiv b^m ~[n]$
The proofs are left as an exercise to the reader :p (Hint: go back to the definition)

Seeing as addition and multiplication are well defined, the integers modulo $n$ form a ring, which we note $\mathbb Z/n\mathbb Z$ . In sage, you can construct such ring with either of the following

Zn = Zmod(5)
Zn = Integers(5)
Zn = IntegerModRing(5)
# Ring of integers modulo 5
Zn(7)
# 2
Zn(8) == Zn(13)
# True

pow(2, 564654533, 7) # Output result as member of Z/7Z
# 4
power_mod(987654321, 987654321, 7) # Output result as simple integer
# 6
Zmod(7)(84564685)^(2^100) # ^ stands for powering in sage. To get XOR, use ^^.
# 5

As a side note, remember that if an equality holds over the integers, then it holds modulo any natural integer $n$ . This can be used to prove that a relation is never true by finding a suitable modulus, or to derive conditions on the potential solutions of the equation.

Example: by choosing an appropriate modulus, show that not even god is able to find integers $a$ and $b$ such that $a^2 = 2 + 4b$

Modular Inverse

Zn = Zmod(10)
Zn(7).is_unit()
# True
Zn(8).is_unit()
# False
3 == 1/Zn(7) == Zn(7)^(-1) == pow(7,-1,10) # member of Z/10Z
# True
inverse_mod(7, 10) # simple integer
# 3
Zn(3)/7
# 9
Zn(3)/8
# ZeroDivisionError: inverse of Mod(8, 10) does not exist
Zn.unit_group()
# Multiplicative Abelian group isomorphic to C4 (C4 being the cyclic group of order 4)

xgcd(7, 10) # find (gcd(a, b), u, v) in au + bv = gcd(a, b)
# (1, 3, -2) <-- (gcd(7, 10), d, -k)

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Modular Arithmetic

Authors: A~Z, perhaps someone else but not yet (or they've decided to remain hidden like a ninja)

Introduction

Congruences

Remark: When $b\neq0$ , we have $a\equiv r~[b]$ , where $r$ is the remainder in the euclidean division of $a$ by

This relation has a number of useful properties:

$\forall c\in \mathbb Z, a\equiv b~[n] \implies ac \equiv bc ~ [n]$
$\forall c \in \mathbb Z, a\equiv b~[n] \implies a+c\equiv b+c ~[n]$
$\forall c \in \mathbb Z, a \equiv b ~[n] \text{ and } b\equiv c~[n]\implies a\equiv c ~[n]$
$\forall m \in \mathbb N, a\equiv b~[n] \implies a^m\equiv b^m ~[n]$
The proofs are left as an exercise to the reader :p (Hint: go back to the definition)

Seeing as addition and multiplication are well defined, the integers modulo $n$ form a ring, which we note $\mathbb Z/n\mathbb Z$ . In sage, you can construct such ring with either of the following

Zn = Zmod(5)
Zn = Integers(5)
Zn = IntegerModRing(5)
# Ring of integers modulo 5
Zn(7)
# 2
Zn(8) == Zn(13)
# True

Powering modulo $n$ is relatively fast, thanks to the algorithm, so we needn't worry about it taking too much time when working with high powers

pow(2, 564654533, 7) # Output result as member of Z/7Z
# 4
power_mod(987654321, 987654321, 7) # Output result as simple integer
# 6
Zmod(7)(84564685)^(2^100) # ^ stands for powering in sage. To get XOR, use ^^.
# 5

Example: by choosing an appropriate modulus, show that not even god is able to find integers $a$ and $b$ such that $a^2 = 2 + 4b$

Modular Inverse

Since we can multiply, a question arises: can we divide? The answer is yes, under certain conditions. Dividing by an integer $c$ is the same as multiplying by its inverse; that is we want to find another integer $d$ such that $cd\equiv 1~[n]$ . Since $cd\equiv 1~[n]\iff\exists k\in\mathbb Z, cd = 1 + kn$ , it is clear from that such an inverse exists if and only if $\gcd(c, n) = 1$ . Therefore, the units modulo $n$ are the integers coprime to $n$ , lying in a set we call the unit group modulo $n$ : $\left(\mathbb Z/n\mathbb Z\right)^\times$

Zn = Zmod(10)
Zn(7).is_unit()
# True
Zn(8).is_unit()
# False
3 == 1/Zn(7) == Zn(7)^(-1) == pow(7,-1,10) # member of Z/10Z
# True
inverse_mod(7, 10) # simple integer
# 3
Zn(3)/7
# 9
Zn(3)/8
# ZeroDivisionError: inverse of Mod(8, 10) does not exist
Zn.unit_group()
# Multiplicative Abelian group isomorphic to C4 (C4 being the cyclic group of order 4)

Finding the modular inverse of a number is an easy task, thanks to the (that outputs solutions in $d$ and $k$ to the equation $cd-kn=1$ from above).

xgcd(7, 10) # find (gcd(a, b), u, v) in au + bv = gcd(a, b)
# (1, 3, -2) <-- (gcd(7, 10), d, -k)

PreviousEuclidean Algorithm NextTheorems of Wilson, Euler, and Fermat

Last updated 3 years ago

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