What Are All the Homomorphisms from Z to Z?

In summary: The general result is that the homomorphisms between finite cyclic groups Z_m and Z_n themselves form a cyclic group of order gcd(m,n).You should be able to prove that everything is determined by where 1 goes. If you cannot, you might try an easier book.
  • #1
redrzewski
117
0
I've started self-studying algebra. So I want to err on the side of getting guidance so I don't get off on the wrong track. This is problem 2.4.4 in Artin.

Describe all homomorphisms from Z+ to Z+ (all integers under addition). Determine if they are injective, surjective, or isomorphisms.

So I need ALL the functions f s.t. f(x+y) = f(x) + f(y) for all integers x,y.

Clearly any linear function f will do this, and these are all isomorphisms.
Also f(x) = 0 for all x satisfies the definition of the homomorphism. This is not injective, surjective, nor an isomorphism.

So far so good?

I don't know of any way to prove that there are no other such functions that will satisfy the definition of a homomorphism.

Any hints?

thanks
 
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  • #2
Z is the infinite cyclic group generated by 1 with identity 0. to specify a homomorphism, one only needs to specify the action of the generator

for instance, f(1) = 2000 will define a homomorphism by induction. In fact, there should be infinitely many homomorphism.
 
  • #3
Thanks. I'll look into that. I don't think Artin has presented that result yet.

Since been doing a lot of analysis lately, and ignored that these are integers here. Hence, my initial comment of all linear functions isn't true. Although all linear functions with integer co-efficients should do it.

But then the inverse may not map to integers everywhere. Hence these may not all be isomorphisms.

So now the question makes more sense. I'll dig further.
 
  • #4
oh Obviously there are infinitely many homomorphisms on Z to Z

But could you suggest the number more precisely by using cardinal numbers?
 
  • #5
sukyung said:
oh Obviously there are infinitely many homomorphisms on Z to Z

But could you suggest the number more precisely by using cardinal numbers?

As was stated above, a homomorphism from a cyclic group is defined by where it sends one generator. You can send 1 to any integer and get a homomorphism from Z to Z, and so there are as many such maps as there are integers.
 
  • #6
Tinyboss said:
As was stated above, a homomorphism from a cyclic group is defined by where it sends one generator. You can send 1 to any integer and get a homomorphism from Z to Z, and so there are as many such maps as there are integers.

For example, H: Z_12 -> Z_5

and Z_12 is a cyclic group but it cannot create a homorphism to Z_5 by specifying H(1).

Then Can I understand it as "we can create a homomorphism by defining each H(1) when the homomorphism is an endomorphism on a cyclic group(like Z)"?
 
  • #7
redrzewski said:
I've started self-studying algebra. So I want to err on the side of getting guidance so I don't get off on the wrong track. This is problem 2.4.4 in Artin.

Describe all homomorphisms from Z+ to Z+ (all integers under addition). Determine if they are injective, surjective, or isomorphisms.

So I need ALL the functions f s.t. f(x+y) = f(x) + f(y) for all integers x,y.

Clearly any linear function f will do this, and these are all isomorphisms.
Also f(x) = 0 for all x satisfies the definition of the homomorphism. This is not injective, surjective, nor an isomorphism.

So far so good?

I don't know of any way to prove that there are no other such functions that will satisfy the definition of a homomorphism.

Any hints?

thanks

Everything is determined by what happens to 1
 
  • #8
sukyung said:
For example, H: Z_12 -> Z_5

and Z_12 is a cyclic group but it cannot create a homorphism to Z_5 by specifying H(1).
Sure we can, and in this case it's unique: H(1)=0, the trivial homomorphism.

Then Can I understand it as "we can create a homomorphism by defining each H(1) when the homomorphism is an endomorphism on a cyclic group(like Z)"?

The general result is that the homomorphisms between finite cyclic groups Z_m and Z_n themselves form a cyclic group of order gcd(m,n).
 
  • #9
you should be able to prove that everything is determined by where 1 goes. If you cannot, you might try an easier book. you should also try to prove that very few of these maps are isomorphisms.
 
  • #10
It's analogous to what you might be used to from linear algebra: any linear map is uniquely determined by its action on basis vectors. (Z is of course a Z-module of rank 1, so it's exactly the same principle.)
 

1. What is a homomorphism?

A homomorphism is a mathematical function that preserves the structure of a group or algebraic system. In other words, it maps elements from one group to another in a way that respects the operations and relationships within the group.

2. What does "homomorphisms on Z to Z" mean?

Homomorphisms on Z to Z refers to all possible mappings or functions from the group of integers (Z) to itself. In this case, the operation being preserved is addition, and the relationships being preserved include the commutative and associative properties.

3. How many homomorphisms are there on Z to Z?

There are infinitely many homomorphisms on Z to Z. This is because any function that maps integers to integers while preserving addition can be considered a homomorphism. Examples include the identity function, where f(x) = x, and the zero function, where f(x) = 0 for all x.

4. What are some common examples of homomorphisms on Z to Z?

Some common examples of homomorphisms on Z to Z include multiplication by a fixed integer, such as f(x) = 2x, and addition by a fixed integer, such as f(x) = x + 5. These functions preserve the structure of the group of integers, as the operation being preserved is addition and the relationships between elements remain unchanged.

5. What is the significance of homomorphisms on Z to Z in mathematics?

Homomorphisms on Z to Z have many applications in mathematics, particularly in abstract algebra and number theory. They can be used to study the properties of groups and rings, and to understand patterns and relationships within the integers. They also have practical applications in fields such as cryptography and coding theory.

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