PlanetMath: ${\mathbb{Z}}

(more info)

Math for the people, by the people.

Main Menu

sections Encyclopædia
Papers
Books
Expositions

meta Requests (200)
Orphanage
Unclass'd
Unproven (490)
Corrections (6)
Classification

talkback Polls
Forums
Feedback
Bug Reports

downloads Snapshots
PM Book

information News
Docs
Wiki
ChangeLog
TODO List
Legalese
About

Entry average rating: No information on entry rating

${\mathbb{Z}}_n$

(Definition)

Let $n \in \mathbb{Z}$ . An equivalence relation, called congruence, can be defined on $\mathbb{Z}$ by $a \equiv b \operatorname{mod} n$ iff divides . Note first of all that $a \equiv b \operatorname{mod} n$ iff $a \equiv b \operatorname{mod} \vert n\vert$ . Thus, without loss of generality, only nonnegative need be considered. Secondly, note that the case is not very interesting. If $a \equiv b \operatorname{mod} 0$ , then 0 divides , which occurs exactly when . In this case, the set of all equivalence classes can be identified with $\mathbb{Z}$ . Thus, only positive need be considered. The set of all equivalence classes of $\mathbb{Z}$ under the given equivalence relation is called ${\mathbb{Z}}_n$ .

Some mathematicians consider the notation ${\mathbb{Z}}_n$ to be archaic and somewhat confusing. This matter of notation is most considerable when for some prime , as ${\mathbb{Z}}_p$ is used to refer to the -adic integers. To avoid this confusion, some mathematicians use the notation $\mathbb{Z}/n\mathbb{Z}$ instead of ${\mathbb{Z}}_n$ . On the other hand, the notation ${\mathbb{Z}}_n$ should not cause confusion when is not prime, and is an intuitive shorthand way to write $\mathbb{Z}/n\mathbb{Z}$ . Thus, others use ${\mathbb{F}}_p$ when for some prime and ${\mathbb{Z}}_n$ otherwise. (The explanation of the usage of $\mathbb{F}_p$ will come later.) Still others, especially those who are unfamiliar with the -adic integers, use the notation ${\mathbb{Z}}_n$ exclusively. (In this entry, the notation ${\mathbb{Z}}_n$ is used exclusively, though it is highly recommended to use another notation when for some prime .)

One usually identifies an element of ${\mathbb{Z}}_n$ (which is technically a class, not a number) with the unique element in the class such that $0 \le r < n$ . One can use the division algorithm to establish that, for each class, an as described exists uniquely. (The set of all 's as described is an example of a residue system.) Thus, the sets ${\mathbb{Z}}_n$ are finite with exactly elements. Addition and multiplication operations can also be defined on ${\mathbb{Z}}_n$ in a natural way that corresponds to the operations on $\mathbb{Z}$ . Under these operations, ${\mathbb{Z}}_n$ is a commutative ring with identity as well as a cyclic ring with behavior . When for some prime , ${\mathbb{Z}}_n$ is a field. In this case, the notation ${\mathbb{F}}_p$ highlights the fact that the structure is a field. When is composite, ${\mathbb{Z}}_n$ has zero divisors and thus is neither a field nor an integral domain. Also note that ${\mathbb{Z}}_1$ is a zero ring, since all integers are equivalent, yielding only one equivalence class.

The in both ${\mathbb{Z}}_n$ and $a \equiv b \operatorname{mod} n$ is called the modulus. Performing computations such as addition, subtraction, multiplication, and taking exponents in one of the rings ${\mathbb{Z}}_n$ is called modular arithmetic.

" ${\mathbb{Z}}_n$ " is owned by Wkbj79.

(view preamble)

See Also: residue systems, $\mathbb{Z}$ , cyclic rings that are isomorphic to $k{\mathbb{Z}}_{kn}$ , congruence, equivalence relation

Other names:

integers mod n

Also defines:

modulus, modular arithmetic

Attachments:: multiplicative order of an integer modulo m (Definition) by alozano

Log in to rate this entry.
(view current ratings)

Cross-references: rings, subtraction, integers, zero ring, integral domain, zero divisors, composite, field, behavior, cyclic ring, commutative ring, operations, multiplication, addition, finite, residue system, division algorithm, number, positive, equivalence classes, without loss of generality, divides, iff, equivalence relation
There are 14 references to this entry.

This is version 21 of ${\mathbb{Z}}_n$ , born on 2006-06-09, modified 2008-02-22.
Object id is 7985, canonical name is MathbbZ_n.
Accessed 4544 times total.

Classification:

AMS MSC:	11-00 (Number theory :: General reference works )
	13M05 (Commutative rings and algebras :: Finite commutative rings :: Structure)
	13-00 (Commutative rings and algebras :: General reference works )

Pending Errata and Addenda

None.[ View all 2 ]

Discussion

forum policy

Interact