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Difference between revisions of "Quotient ring"

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$$(a+I)(b+I)=ab+I.$$
 
$$(a+I)(b+I)=ab+I.$$
  
The quotient turns out to be a ring and is denoted by $R/I$. The mapping $\pi:R\to R/I$, where $\pi(x)=x+I$, is a surjective ring homomorphism, called the natural homomorphism (see [[Algebraic system|Algebraic system]]).
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The quotient turns out to be a ring and is denoted by $R/I$. The mapping $\pi\colon R\to R/I$, where $\pi(x)=x+I$, is a surjective ring homomorphism, called the natural homomorphism (see [[Algebraic system|Algebraic system]]).
  
 
The most important example of a quotient ring is the ring of residues modulo $n$ — the quotient ring of the ring of integers $\mathbf Z$ by the ideal $\mathbf Zn$. The elements of $\mathbf Z/\mathbf Zn$ can be assumed to be the numbers $\{0,\ldots,n-1\}$, where the sum and the product are defined as the remainders on diving the usual sum and product by $n$. One can establish a one-to-one order-preserving correspondence between the ideals of $R/I$ and the ideals of $R$ containing $I$. In particular, $R/I$ is simple (cf. [[Simple ring|Simple ring]]) if and only if $I$ is a [[Maximal ideal|maximal ideal]].
 
The most important example of a quotient ring is the ring of residues modulo $n$ — the quotient ring of the ring of integers $\mathbf Z$ by the ideal $\mathbf Zn$. The elements of $\mathbf Z/\mathbf Zn$ can be assumed to be the numbers $\{0,\ldots,n-1\}$, where the sum and the product are defined as the remainders on diving the usual sum and product by $n$. One can establish a one-to-one order-preserving correspondence between the ideals of $R/I$ and the ideals of $R$ containing $I$. In particular, $R/I$ is simple (cf. [[Simple ring|Simple ring]]) if and only if $I$ is a [[Maximal ideal|maximal ideal]].

Latest revision as of 14:56, 30 December 2018

of a ring $R$ by an ideal $I$

The quotient group of the additive group of $R$ by the subgroup $I$, with multiplication

$$(a+I)(b+I)=ab+I.$$

The quotient turns out to be a ring and is denoted by $R/I$. The mapping $\pi\colon R\to R/I$, where $\pi(x)=x+I$, is a surjective ring homomorphism, called the natural homomorphism (see Algebraic system).

The most important example of a quotient ring is the ring of residues modulo $n$ — the quotient ring of the ring of integers $\mathbf Z$ by the ideal $\mathbf Zn$. The elements of $\mathbf Z/\mathbf Zn$ can be assumed to be the numbers $\{0,\ldots,n-1\}$, where the sum and the product are defined as the remainders on diving the usual sum and product by $n$. One can establish a one-to-one order-preserving correspondence between the ideals of $R/I$ and the ideals of $R$ containing $I$. In particular, $R/I$ is simple (cf. Simple ring) if and only if $I$ is a maximal ideal.


Comments

Another most important example is the quotient ring $F[x]/F[x]f(x)$, where $F[x]$ is the ring of polynomials over $F$ in one variable $x$ and $f(x)$ is an irreducible polynomial. This quotient ring describes all field extensions of $F$ by roots of the equation $f(x)=0$ (cf. also Extension of a field).

References

[a1] P.M. Cohn, "Algebra" , 1 , Wiley (1982) pp. Sect. 10.1
How to Cite This Entry:
Quotient ring. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Quotient_ring&oldid=43588
This article was adapted from an original article by L.A. Skornyakov (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article