Field of fractions explained

In abstract algebra, the field of fractions of an integral domain is the smallest field in which it can be embedded. The construction of the field of fractions is modeled on the relationship between the integral domain of integers and the field of rational numbers. Intuitively, it consists of ratios between integral domain elements.

The field of fractions of an integral domain

is sometimes denoted by

\operatorname{Frac}(R)

\operatorname{Quot}(R)

, and the construction is sometimes also called the fraction field, field of quotients, or quotient field of

. All four are in common usage, but are not to be confused with the quotient of a ring by an ideal, which is a quite different concept. For a commutative ring that is not an integral domain, the analogous construction is called the localization or ring of quotients.

Definition

Given an integral domain

and letting

R^*=R\setminus\{0\}

, we define an equivalence relation on

R x R^*

by letting

(n,d)\sim(m,b)

whenever

nb=md

. We denote the equivalence class of

(n,d)

	n
	d

. This notion of equivalence is motivated by the rational numbers

, which have the same property with respect to the underlying ring

of integers.

Then the field of fractions is the set

Frac(R)=(R x R^*)/\sim

with addition given by

	n
	d

	m
	b

	nb+md
	db

and multiplication given by

	n
	d

⋅

	m
	b

	nm
	db

One may check that these operations are well-defined and that, for any integral domain

Frac(R)

is indeed a field. In particular, for

n,d ≠ 0

, the multiplicative inverse of

	n
	d

is as expected:

	d
	n

⋅

	n
	d

The embedding of

\operatorname{Frac}(R)

maps each

to the fraction

	en
	e

for any nonzero

e\inR

(the equivalence class is independent of the choice

). This is modeled on the identity

	n
	1

The field of fractions of

is characterized by the following universal property:

h:R\toF

is an injective ring homomorphism from

into a field

, then there exists a unique ring homomorphism

g:\operatorname{Frac}(R)\toF

that extends

There is a categorical interpretation of this construction. Let

be the category of integral domains and injective ring maps. The functor from

to the category of fields that takes every integral domain to its fraction field and every homomorphism to the induced map on fields (which exists by the universal property) is the left adjoint of the inclusion functor from the category of fields to

. Thus the category of fields (which is a full subcategory) is a reflective subcategory of

with no nonzero zero divisors. The embedding is given by

r\mapsto	rs
	s

for any nonzero

s\inR

.^[1]

Examples

The field of fractions of the ring of integers is the field of rationals:

\Q=\operatorname{Frac}(\Z)

R:=\{a+bi\mida,b\in\Z\}

be the ring of Gaussian integers. Then

\operatorname{Frac}(R)=\{c+di\midc,d\in\Q\}

, the field of Gaussian rationals.

The field of fractions of a field is canonically isomorphic to the field itself.
Given a field

, the field of fractions of the polynomial ring in one indeterminate

K[X]

(which is an integral domain), is called the , field of rational fractions, or field of rational expressions^[2] ^[3] ^[4] ^[5] and is denoted

K(X)

The field of fractions of the convolution ring of half-line functions yields a space of operators, including the Dirac delta function, differential operator, and integral operator. This construction gives an alternate representation of the Laplace transform that does not depend explicitly on an integral transform.^[6]

Generalizations

Localization

See main article: Localization (commutative algebra).

and any multiplicative set

, the localization

S^-1R

is the commutative ring consisting of fractions

	r
	s

with

r\inR

and

s\inS

, where now

(r,s)

is equivalent to

(r',s')

if and only if there exists

t\inS

such that

t(rs'-r's)=0

Two special cases of this are notable:

is the complement of a prime ideal

, then

S^-1R

is also denoted

R_P

.
When

is an integral domain and

is the zero ideal,

R_P

is the field of fractions of

is the set of non-zero-divisors in

, then

S^-1R

is called the total quotient ring.
The total quotient ring of an integral domain is its field of fractions, but the total quotient ring is defined for any commutative ring.

Note that it is permitted for

to contain 0, but in that case

S^-1R

will be the trivial ring.

Semifield of fractions

The semifield of fractions of a commutative semiring with no zero divisors is the smallest semifield in which it can be embedded.

are equivalence classes written as

	a
	b

with

and

Notes and References

Book: Hungerford. Thomas W.. Algebra. 1980. Springer. New York. 3540905189. 142–144. Revised 3rd.
Book: Vinberg, Ėrnest Borisovich . A course in algebra . 2003 . 131 . 978-0-8218-8394-5 . American Mathematical Society.
Book: Foldes, Stephan . Fundamental structures of algebra and discrete mathematics . Wiley . 1994. 128. registration . 0-471-57180-6.
Book: Grillet, Pierre Antoine . 3.5 Rings: Polynomials in One Variable . https://books.google.com/books?id=LJtyhu8-xYwC&pg=PA124. Abstract algebra. 2007. 124 . 978-0-387-71568-1 . Springer.
Book: Marecek . Lynn . Mathis . Andrea Honeycutt . Intermediate Algebra 2e . 6 May 2020 . . Houston, Texas -->. §7.1.
Book: Mikusiński, Jan . Operational Calculus. 14 July 2014 . Elsevier . 9781483278933 .

Field of fractions explained

Definition

Examples

Generalizations

Localization

Semifield of fractions

See also

Notes and References