Consider the finite set of whole numbers {0,1,2}. Define addition and multiplication such that this set...

Linear Algebra Prove that Q, the set of rational numbers, with the usually addition and multiplication,...

Linear Algebra Prove that Q, the set of rational numbers, with the usually addition and multiplication, is a field.

1. Consider the set (Z,+,x) of integers with the usual addition (+) and multiplication (x) operations....

1. Consider the set (Z,+,x) of integers with the usual addition (+) and multiplication (x) operations. Which of the following are true of this set with those operations? Select all that are true. Note that the extra "Axioms of Ring" of Definition 5.6 apply to specific types of Rings, shown in Definition 5.7. - Z is a ring - Z is a commutative ring - Z is a domain - Z is an integral domain - Z is a field...

I do not understand the following statement in my textbook. "The finite set {0,1,2,3,4} is a...

I do not understand the following statement in my textbook. "The finite set {0,1,2,3,4} is a field when addition and multiplication are computed modelo 5." How is this true? A field is a set where addition and multiplication are well defined operations for commutative, associative properties, and they obey the distributive property.

Consider the set of all ordered pairs of real numbers with standard vector addition but with...

Consider the set of all ordered pairs of real numbers with standard vector addition but with scalar multiplication defined by  k(x,y)=(k^2x,k^2y). I know this violates (alpha + beta)x = alphax + betax, but I'm not for sure how to figure that out? How would I figure out which axioms it violates?

Let V be the set of all triples (r,s,t) of real numbers with the standard vector...

Let V be the set of all triples (r,s,t) of real numbers with the standard vector addition, and with scalar multiplication in V defined by k(r,s,t) = (kr,ks,t). Show that V is not a vector space, by considering an axiom that involves scalar multiplication. If your argument involves showing that a certain axiom does not hold, support your argument by giving an example that involves specific numbers. Your answer must be well-written.

Let V be the set of all ordered pairs of real numbers. Consider the following addition...

Let V be the set of all ordered pairs of real numbers. Consider the following addition and scalar multiplication operations V. Let u = (u1, u2) and v = (v1, v2). • u ⊕ v = (u1 + v1 + 1, u2 + v2 + ) • ku = (ku1 + k − 1, ku2 + k − 1) Show that V is not a vector space.

Let V be the set of all ordered pairs of real numbers. Consider the following addition...

Let V be the set of all ordered pairs of real numbers. Consider the following addition and scalar multiplication operations V. Let u = (u1, u2) and v = (v1, v2). • u ⊕ v = (u1 + v1 + 1, u2 + v2 + ) • ku = (ku1 + k − 1, ku2 + k − 1) 1)Show that the zero vector is 0 = (−1, −1). 2)Find the additive inverse −u for u = (u1, u2). Note:...

Consider the set Q(√3) ={a+b√3| a,b∈Q}. We have the associative properties of usual addition and usual...

Consider the set Q(√3) ={a+b√3| a,b∈Q}. We have the associative properties of usual addition and usual multiplication from the field of real number R. a)Show that Q (√3) is closed under addition, contains the additive identity (0,zero) of R, each element contains the additive inverses, and say if addition is commutative. What does this tell you about (Q(√3,+)? b) Prove that Q(√3) is a commutative ring with unity 1 c) Prove that Q(√3) is a field by showing every nonzero...

Let n=60, not a product of distinct prime numbers. Let B_n= the set of all positive...

Let n=60, not a product of distinct prime numbers. Let B_n= the set of all positive divisors of n. Define addition and multiplication to be lcm and gcd as well. Now show that B_n cannot consist of a Boolean algebra under those two operators. Hint: Find the 0 and 1 elements first. Now find an element of B_n whose complement cannot be found to satisfy both equalities, no matter how we define the complement operator.

Problem 1. In this problem we work in the finite field 25, i.e. the numbers (mod...

Problem 1. In this problem we work in the finite field 25, i.e. the numbers (mod 5). 1. Show that 2 is a primitive 4-th root of 1. 2. Show that X1-1= (x - 2)(x - 22)(x - 2)(X – 24). 3. Show that g(x) = (x - 2)(X - 4) generates a cyclic code C with d>3. (Hint: invoke a property that we have shown in class.) 4. What is the generating matrix G of the code C given...