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Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET PDF Download

A ring A is a set with + , • such that

(1) (A, +) is an abelian group;
(2) (A, •) is a semigroup;
(3) • distributes over + on both sides.
(4) (∀x, y ∈ A) x • y = y • x
(5) (∃1 ∈ A)(∀x ∈ A) 1•x = x•1 = x .


In this course all rings A are commutative, that is, and have an identity element 1 (easily seen to be unique)

If 1 = 0 then A = {0} (easy to see), called the zero ring.


Multiplication will be denoted by juxtaposition, and simple facts used without comment, such as

(∀x, y ∈ A)
x 0 = 0 ,
(−x)y = x(−y) = −(xy) ,
(−x)(−y) = xy 


Call a subset S of a ring A a subring if

(i) 1 ∈ S ;
(ii) (∀x, y ∈ S ) x + y , xy , −x ∈ S .


Condition (ii) is easily seen to be equivalent to

(ii)′ (∀x, y ∈ S ) x − y , xy ∈ S .

 

Note: In other contexts authors replace the condition 1 ∈ S by S ≠ ∅ (which is not equivalent!).


Examples:

(1) Z is the only subring of Z .

(2) Z is a subring of Q , which is a subring of R , which is a subring of C .

(3) Z[i] = { a + bi | a, b ∈ Z } Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

the ring of Gaussian integers is a subring of C 

(4) Zn = { 0, 1, . . . , n − 1}

with addition and multiplication mod n .

(Alternatively Zn may be defined to be the quotient ring Z/nZ , defined below)

(5) R any ring, x an indeterminate. Put

R[[x]] = {a0 + a1x + a2x2 + . . . | a0, a1, . . . ∈ R} , the set of formal power series over R , which becomes a ring under addition and multiplication of power series. Important subring:

R[x] = {a0 + a1x + . . . +anxn | n ≥ 0 , a0, a1, . . . , an ∈ R} 

the ring of polynomials over R .

Call a mapping f : A → B (where A and B are rings) a ring homomorphism if

(a) f (1) = 1 ;

(b) (∀x, y ∈ A) f (x + y) = f (x) + f (y)
and
f (xy) = f (x)f (y) ,


in which case the following are easily checked:

(i) f (0) = 0 ;
(ii) (∀x ∈ A) f (−x) = −f (x) ;
(iii) f (A) = {f (x) | x ∈ A} , the image of f is a subring of B ;
(iv) Composites of ring hom’s are ring hom’s.


An isomorphism is a bijective homomorphism, say f : A → B , in which case we write

A ≌ B or f : A ≌ B.

It is easy to check that

≌ is an equivalence relation.

A nonempty subset I of a ring A is called an ideal, written Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

(i) (∀x, y ∈ I ) x + y , −x ∈ I 

[clearly equivalent to (i)′ (∀x, y ∈ I ) x − y ∈ I ]:

(ii) (∀x ∈ I )(∀y ∈ A) xy ∈ I .


In particular I is an additive subgroup of A , so we can form the quotient group the group of cosets of I ,

A/I = { I + a | a ∈ A} ,

with addition defined by, for a, b ∈ A , (I + a) + (I + b) = I + (a + b) .

Further A/I forms a ring by defining, for a, b ∈ A ,

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

Verification of the ring axioms is straightforward:


— only tricky bit is first checking multiplication is well-defined:

If I + a = I + a′ and I + b = I + b′ then

a − a′ , b − b′ ∈ I ,

so

ab − a′b′ = ab − ab′ + ab′ − a′b′

= a(b − b′) + (a − a′)b′ ∈ I 

yielding I + ab = I + a′b′ .

We call A/I a quotient ring.

The mapping

φ : A → A/I , x → I + x

is clearly a surjective ring homomorphism, called the natural map, whose kernel is

ker φ = {x ∈ A | I + x = I} = I .

Thus all ideals are kernels of ring homomorphisms.

The converse is easy to check, so

kernels of ring homomorphisms with domain A are precisely ideals of A .


The following important result is easy to verify:

Fundamental Homomorphism

Theorem: If f : A → B is a ring homomorphism with kernel I and image C then

A/I ≌ C .

 

Proposition: Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET and φ : A → A/I be the natural map. Then
(i) ideals J of A/I have the form J = J/I = {I + j | j ∈ J} for some J such that I ⊆ J  A ; (ii) φ−1 is an inclusion-preserving bijection between ideals of A/I and ideals of A containing I .

 

Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Example: The ring Zn = {0, 1, . . . , n − 1} with mod n arithmetic is isomorphic to Z/nZ : follows from the Fundamental Homomorphism

Theorem, by observing that the mapping f : Z → Zn where

f (z) = remainder after dividing z by n is a ring homomorphism with image Zn and kernel nZ.

The document Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET is a part of the Mathematics Course Mathematics for IIT JAM, GATE, CSIR NET, UGC NET.
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FAQs on Rings, Ideals, Quotient Rings - Ring Theory, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is a ring in ring theory?
Ans. In ring theory, a ring is a mathematical structure consisting of a set equipped with two binary operations, addition and multiplication, that satisfy certain properties. These properties include closure under addition and multiplication, associativity of addition and multiplication, distributivity of multiplication over addition, and the existence of additive and multiplicative identities.
2. What are ideals in ring theory?
Ans. In ring theory, an ideal is a subset of a ring that is closed under addition, subtraction, and multiplication by elements of the ring. Additionally, an ideal must absorb multiplication by elements of the ring. Ideals play a crucial role in the study of rings as they provide a way to factor out certain elements and study the quotient ring.
3. What are quotient rings in ring theory?
Ans. Quotient rings, also known as factor rings, are a construction in ring theory that allow us to create a new ring by factoring out an ideal from the original ring. The quotient ring consists of cosets of the ideal, where each coset represents a distinct element of the quotient ring. The operations of addition and multiplication in the quotient ring are defined in terms of the cosets.
4. How do ideals relate to quotient rings in ring theory?
Ans. Ideals are closely related to quotient rings in ring theory. Given a ring R and an ideal I in R, we can define a natural ring homomorphism from R to the quotient ring R/I. This homomorphism maps each element of R to its coset in the quotient ring. The kernel of this homomorphism is precisely the ideal I. This connection allows us to study properties of the ring R by analyzing its quotient ring R/I.
5. How are rings, ideals, and quotient rings used in CSIR-NET Mathematical Sciences exam?
Ans. Rings, ideals, and quotient rings are important topics in abstract algebra, which is a significant part of the CSIR-NET Mathematical Sciences exam syllabus. Questions related to these concepts often appear in the algebra section of the exam. Understanding the properties and applications of rings, ideals, and quotient rings is crucial for solving problems and demonstrating a strong foundation in algebra for the exam.
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