Rings and Fields: Understanding Polynomials as a Commutative Ring with Unity

In summary, the conversation discusses whether the set of all polynomials is a ring and a field. It is determined that it is a commutative ring with unity, but it is uncertain if every non-zero element has an inverse to constitute a field. It is concluded that there are no multiplicative inverses in this set of polynomials because there is no polynomial that would give a multiplicative inverse, and a rational function would need to be used instead. The conversation also brings up the concept of the degree of polynomials and how it relates to multiplication.
  • #1
oddiseas
73
0

Homework Statement



is the set of all polynomials a ring,and a fieldd.Is is commutative and does it have unity

Homework Equations





The Attempt at a Solution



now if we add or multiply any polynomials we get a polynomial. So it is a ring, but i am not sure what the multiplicative inverse is or whether every non zero element has an inverse to constitute a field.
 
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  • #2
Multiplication is just ordinary multiplication of polynomials and the identity is the "constant" polynomial p(x)= 1 for all x. Does there exist a polynomial p(x) such that (x-1)(p(x))= 1? Think about the degree of p and what multiplication of polynomials does to degrees.
 
  • #3
i am thinking that we do not have multiplicative inverses because there is no polynomial that would give one, we would need to use a rational function, is this a correct assesmnent?
 
  • #4
Yes, but to give a complete answer, you need to say why "no polynomial would give one" (I presume you mean there is no polynomial, p(x), such that (x-1)p(x)= 1.)

Again, think of the "degree" of polynomials. The degree of x- 1 is 1. What could the degree of (x-1)p(x) be? Could it be equal to 0, the degree of the constant polynomial, 1?
 
  • #5
ok thanks
 

FAQ: Rings and Fields: Understanding Polynomials as a Commutative Ring with Unity

What is a ring?

A ring is a mathematical structure that consists of a set of elements and two operations, usually addition and multiplication. These operations follow certain rules, such as closure and associativity, and the set must also contain an identity element for each operation. Rings are used to study algebraic structures and can be applied to various areas of mathematics.

What is a field?

A field is a type of ring that has additional properties. In addition to satisfying the rules of a ring, a field also has the property of invertibility, meaning that every non-zero element has a multiplicative inverse. This means that every element can be divided by any other non-zero element. Common examples of fields include the real numbers, complex numbers, and rational numbers.

How are rings and fields related to polynomials?

Polynomials can be thought of as expressions that involve variables and coefficients, which can be combined using operations such as addition, subtraction, and multiplication. The set of all polynomials with coefficients from a particular ring or field forms a commutative ring or a field, respectively. This means that the operations of addition and multiplication follow the rules of commutativity and associativity, and there is an identity element for each operation.

What is the importance of understanding polynomials as a commutative ring with unity?

Understanding polynomials as a commutative ring with unity allows for the application of abstract algebraic concepts to the study of polynomials. This can lead to a deeper understanding of the properties and behavior of polynomials, as well as their connections to other areas of mathematics. It also allows for the use of powerful tools and techniques from abstract algebra, such as the study of ideals, to analyze polynomials and their properties.

How are rings and fields used in real-world applications?

Rings and fields have numerous real-world applications, particularly in the fields of computer science, cryptography, and physics. They are used in coding theory, error-correcting codes, and encryption algorithms. In physics, rings and fields are used to study symmetry and algebraic structures in areas such as quantum mechanics and particle physics. They are also used in economic and financial models, such as in the study of stock market behavior.

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