Prove the division algorithm for R[x]. Where R[x] is the set of real polynomials.

Let R[x] be the set of all polynomials (in the variable x) with real coefficients. Show...

Let R[x] be the set of all polynomials (in the variable x) with real coefficients. Show that this is a ring under ordinary addition and multiplication of polynomials. What are the units of R[x] ? I need a legible, detailed explaination

In the ring R[x] of polynomials with real coefficients, show that A = {f 2 R[x]...

In the ring R[x] of polynomials with real coefficients, show that A = {f 2 R[x] : f(0) = f(1) = 0} is an ideal.

Prove that the singleton set {0} is a vector subspace of the space P4(R) of all...

Prove that the singleton set {0} is a vector subspace of the space P4(R) of all polynomials of degree at most 3 with real coefficients.

Let V be the set of polynomials of the form ax + (a^2)(x^2), for all real...

Let V be the set of polynomials of the form ax + (a^2)(x^2), for all real numbers a. Is V a subspace of P?

4. Prove that {(x, y) ∈ R 2 ∶ x − y ∈ Q} is an...

4. Prove that {(x, y) ∈ R 2 ∶ x − y ∈ Q} is an equivalence relation on the set of real numbers, where Q denotes the set of rational numbers.

5. Let S be the set of all polynomials p(x) of degree ≤ 4 such that...

5. Let S be the set of all polynomials p(x) of degree ≤ 4 such that p(-1)=0. (a) Prove that S is a subspace of the vector space of all polynomials. (b) Find a basis for S. (c) What is the dimension of S? 6. Let ? ⊆ R! be the span of ?1 = (2,1,0,-1), ?2 =(1,2,-6,1), ?3 = (1,0,2,-1) and ? ⊆ R! be the span of ?1 =(1,1,-2,0), ?2 =(3,1,2,-2). Prove that V=W.

Prove if on the real number line R , set A = 0, B = 1,...

Prove if on the real number line R , set A = 0, B = 1, X = x and Y = y (for some x , y ∈ R ) then the condition that X , Y are harmonic conjugates with respect to A , B (i.e. ( A , B ; X , Y ) = − 1) means 1/x + 1/y = 2

State the Division Algorithm for Natural number and prove it using induction

State the Division Algorithm for Natural number and prove it using induction

Prove that the set V of all polynomials of degree ≤ n including the zero polynomial...

Prove that the set V of all polynomials of degree ≤ n including the zero polynomial is vector space over the field R under usual polynomial addition and scalar multiplication. Further, find the basis for the space of polynomial p(x) of degree ≤ 3. Find a basis for the subspace with p(1) = 0.

Show (-1,1)~R (where R= set of real numbers) by f(x)= x/(1-|x|) Use this to show g(x)=x/(d-|x|)...

Show (-1,1)~R (where R= set of real numbers) by f(x)= x/(1-|x|) Use this to show g(x)=x/(d-|x|) is also a bijection (i.e. g: (-d,d)->R) Finally consider h(x)= x + (a+b)/2 and show it is a bijection where h: (-d,d)->(a,b) Conclude: R~(a,b)