If A and B are both rings, with addition and multiplication, there is also a multiplicative condition: 
by the homomorphism property. Since f(0R) has an additive inverse in S, we can add it to both sides of this equation to get 0S = f(0R).
is a ring homomorphism (and as such, it is a homomorphism of additive groups).
is complex conjugation. Then c is a homomorphism from C to itself. It is clearly a bijection, so it is in fact an isomorphism from C to itself.
Then there is an evaluation homomorphism 
is the ring of polynomials with coefficients in R.
is a group homomorphism. Note that R is an additive group and R* the set of nonzero real numbers, is a multiplicative group. The verification that f is a group homomorphism is precisely the law of exponents: 
the latter being a group under multiplication. The value 
is called the sign of σ, and is important in many applications, including one definition of the 
be a group homomorphism. The kernel of f, ker (f), is the subset of G consisting of elements G such that 
is the group identity element).
be a ring homomorphism. The kernel of 
is the subset of R consisting of elements R such that 
is the trivial homomorphism, then ker 
the trivial subgroup of H
consisting of multiples of n. The image is all of Zn; reduction mod n is surjective.
Which polynomials with rational coefficients vanish on 
(See the algebraic number theory wiki for an answer.)
of positive real numbers.
The image of the sign homomorphism is 
since the sign is a nontrivial map, so it takes on both 
for certain permutations.
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Homomorphisms are the maps between algebraic objects. There are two main types: group homomorphisms and ring homomorphisms. (Other examples include vector spacehomomorphisms, which are generally called linear maps, as well as homomorphisms of modules and homomorphisms of algebras.)
Generally speaking, a homomorphism between two algebraic objects A, B is a function f : A → B which preserves the algebraic structure on A and B That is, if elements in A satisfy some algebraic equation involving addition or multiplication, their images in B satisfy the same algebraic equation. The details of the definitions of homomorphisms in various contexts depend on the algebraic structures of A and B.
EXAMPLE If the operations on A and B are both addition, then the homomorphism condition is |
A bijective homomorphism is called an isomorphism. An isomorphism between two algebraic objects and identifies them with each other; they are, in an algebraic sense, the same object (possibly written in two different ways). The most common use of homomorphisms in abstract algebra is via the three so-called isomorphism theorems, which allow for the identification of certain quotient objects with certain other subobjects (subgroups, subrings, etc.)
The study of the interplay between algebraic objects is fundamental in the study of algebra. The existence and properties of homomorphisms from one algebraic object to another give a rich depth of information about the objects and their relationship. Many important concepts in abstract algebra, such as
the integers modulo n
a prime ideal in a ring
the sign of a permutation,
can be naturally considered as (respectively) the image of a homomorphism, the kernel of a homomorphism, or the homomorphism itself.
Definitions and Examples
Let A and B be groups, with operations given by ºA and ºB respectively. A group homomorphism f : A → B is a function f such that  for all x,y ∈ A. |
DEFINATION Let R and S be rings, with operations + and . (this is a slight abuse of notation, but the formulas below are more unwieldy with subscripts on the operations). A ring homomorphism f : R → S is a function f such that
(In this wiki, "ring" means "ring with unity"; a homomorphism of rings is defined in the same way, but without the third condition.) |
In both cases, a homomorphism is called an isomorphism if it is bijective.
EXAMPLE Show that if f : R → S is a ring homomorphism, f(0R) = os. Note that |
EXAMPLE 1. For any groups G and H, there is a trivial homomorphis |
Kernel and Image
Any homomorphism f : A → B has two objects associated to it: the kernel, which is a subset of A, and the image, which is a subset of B.
DEFINATION
|
For further exploration of the kernel in the setting of vector spaces, see the wiki.
The kernel of a homomorphism is an important object, in both group and ring theory. The following theorem identifies what kind of object it is:
EXAMPLE Continuing the six examples above: 1. If |
Properties of Homomorphisms
- Composition: The composition of homomorphisms is a homomorphism. That is, if
are homomorphisms, then 
is a homomorphism as well. - Isomorphisms: If f is an isomorphism, which is a bijective homomorphism, then
is also a homomorphism. (Compare with homeomorphism, a similar concept in topology, which is a continuous function with a continuous inverse; a bijective continuous function does not necessarily have a continuous inverse.) - Injectivity and the kernel: A group homomorphism f is injective if and only if its kernel ker(f) equals {1}, where denotes the identity element of the domain. A ring homomorphism is injective if and only if its kernel equals {0} where 0 denotes the additive identity of the domain.
- Field homomorphisms: If R is a field and S is not the zero ring, then any homomorphism
is injective. (Proof: the kernel is an ideal, and the only ideals in a field are the entire field and the zero ideal. Since 
it must be the latter.)
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FAQs on Homomorphism - Group Theory, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET
| 1. What is a homomorphism in group theory? |  |
| 2. What is the significance of a homomorphism in group theory? | |
Homomorphisms play a crucial role in group theory as they provide a way to study the relationship between different groups. By examining the properties of homomorphisms, we can analyze the structural similarities and differences between groups. Homomorphisms also help in classifying groups and identifying their subgroups. Moreover, they allow us to define quotient groups and factor groups, which are important concepts in group theory.
| 3. How can we determine if a given function is a homomorphism? | |
To determine if a given function is a homomorphism, we need to check if it preserves the group operation. This means verifying whether the function satisfies the condition f(x * y) = f(x) * f(y) for all elements x and y in the domain of the function. By substituting different pairs of elements and evaluating the function using the group operation, we can check if the equation holds true. If the equation is satisfied for all elements, the function is a homomorphism; otherwise, it is not.
| 4. What are the different types of homomorphisms in group theory? | |
In group theory, there are several types of homomorphisms:
- Monomorphism: A monomorphism is an injective homomorphism, meaning that it preserves distinctness. It maps different elements of the domain group to different elements of the codomain group.
- Epimorphism: An epimorphism is a surjective homomorphism, meaning that it covers the entire codomain. It maps every element of the codomain group to at least one element of the domain group.
- Isomorphism: An isomorphism is a bijective homomorphism, combining the properties of both monomorphisms and epimorphisms. It establishes a one-to-one correspondence between the elements of the domain and codomain groups, preserving the group structure.
- Endomorphism: An endomorphism is a homomorphism where the domain and codomain groups are the same.
- Automorphism: An automorphism is an isomorphism where the domain and codomain groups are the same, resulting in a self-mapping of the group.
| 5. Can all groups be mapped by a homomorphism onto another group? | |
No, not all groups can be mapped by a homomorphism onto another group. The existence of a homomorphism from one group to another depends on the structural properties of the groups involved. For example, if there is no element in the codomain group that satisfies the condition f(x) = y for any x in the domain group, then there is no homomorphism between the two groups. Additionally, the sizes of the groups can also limit the possibility of a homomorphism. For instance, if the domain group has more elements than the codomain group, it is not possible to have a surjective homomorphism.
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