Let P be the vector space of all polynomials in x with real coefficients. Does P...

Let P2 denote the vector space of polynomials in x with real coefficients having degree at...

Let P2 denote the vector space of polynomials in x with real coefficients having degree at most 2. Let W be a subspace of P2 given by the span of {x2−x+6,−x2+2x−1,x+5}. Show that W is a proper subspace of P2.

If V is a vector space of polynomials of degree n with real numbers as coefficients,...

If V is a vector space of polynomials of degree n with real numbers as coefficients, over R, and W is generated by the polynomials (x 3 + 2x 2 − 2x + 1, x3 + 3x 2 − x + 4, 2x 3 + x 2 − 7x − 7), then is W a subspace of V , and if so, determine its basis.

Let P4 denote the space of polynomials of degree less than 4 with real coefficients. Show...

Let P4 denote the space of polynomials of degree less than 4 with real coefficients. Show that the standard operations of addition of polynomials, and multiplication of polynomials by a scalar, give P4 the structure of a vector space (over the real numbers R). Your answer should include verification of each of the eight vector space axioms (you may assume the two closure axioms hold for this problem).

Let P(R) denote the family of all polynomials (in a single variable x) with real coefficients....

Let P(R) denote the family of all polynomials (in a single variable x) with real coefficients. We have seen that with the operations of pointwise addition and multiplication by scalars, P(R) is a vector space over R. Consider the 2 linear maps D, I : P(R) to P(R), where D is differentiation and I is anti-differentiation. In detail, for a polynomial p = a0+a1x1+...+anxn, we have D(p) = a1+2a2x+....+nanxn-1 and I(p) = a0x+(a1/2)x2+...+(an/(n+1))xn+1. a. Show that D composed with I...

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.

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

Let V be a vector space: d) Suppose that V is finite-dimensional, and let S be...

Let V be a vector space: d) Suppose that V is finite-dimensional, and let S be a set of inner products on V that is (when viewed as a subset of B(V)) linearly independent. Prove that S must be finite e) Exhibit an infinite linearly independent set of inner products on R(x), the vector space of all polynomials with real coefficients.

Let V = Pn(R), the vector space of all polynomials of degree at most n. And...

Let V = Pn(R), the vector space of all polynomials of degree at most n. And let T : V → V be a linear transformation. Prove that there exists a non-zero linear transformation S : V → V such that T ◦ S = 0 (that is, T(S(v)) = 0 for all v ∈ V) if and only if there exists a non-zero vector v ∈ V such that T(v) = 0. Hint: For the backwards direction, consider building...

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 the set W be: all polynomials in P3 satisfying that p(-t)=p(t), Question: Is W a...

Let the set W be: all polynomials in P3 satisfying that p(-t)=p(t), Question: Is W a vector space or not? If yes, find a basis and dimension