Find an inner product on vector space P of polynomials that makes x and y orthogonal....

Question 1:  Is there a vector space that can not be an inner product space? Justify your...

Question 1:  Is there a vector space that can not be an inner product space? Justify your answer. Part 2: Suppose that u and v are two non-orthogonal vectors in an inner product space V,< , >. Question 2: Can we modify the inner product < , > to a new inner product so that the two vectors become orthogonal? Justify your answer.

Let V be a finite dimensional vector space over R with an inner product 〈x, y〉...

Let V be a finite dimensional vector space over R with an inner product 〈x, y〉 ∈ R for x, y ∈ V . (a) (3points) Let λ∈R with λ>0. Show that 〈x,y〉′ = λ〈x,y〉, for x,y ∈ V, (b) (2 points) Let T : V → V be a linear operator, such that 〈T(x),T(y)〉 = 〈x,y〉, for all x,y ∈ V. Show that T is one-to-one. (c) (2 points) Recall that the norm of a vector x ∈ V...

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

Let P be the vector space of all polynomials in x with real coefficients. Does P have a basis? Prove your answer.

1. V is a subspace of inner-product space R3, generated by vector u =[2 2 1]T...

1. V is a subspace of inner-product space R3, generated by vector u =[2 2 1]T and v =[ 3 2 2]T. (a) Find its orthogonal complement space V┴ ; (b) Find the dimension of space W = V+ V┴; (c) Find the angle θ between u and v and also the angle β between u and normalized x with respect to its 2-norm. (d) Considering v’ = av, a is a scaler, show the angle θ’ between u and...

A2. Let v be a fixed vector in an inner product space V. Let W be...

A2. Let v be a fixed vector in an inner product space V. Let W be the subset of V consisting of all vectors in V that are orthogonal to v. In set language, W = { w LaTeX: \in ∈V: <w, v> = 0}. Show that W is a subspace of V. Then, if V = R3, v = (1, 1, 1), and the inner product is the usual dot product, find a basis for W.

Part 1: We've seen that most of the vector spaces can be equipped with inner product...

Part 1: We've seen that most of the vector spaces can be equipped with inner product functions.    Question 1:  Is there a vector space that can not be an inner product space? Justify your answer. Part 2: Suppose that u and v are two non-orthogonal vectors in an inner product space V,< , >. Question 2: Can we modify the inner product < , > to a new inner product so that the two vectors become orthogonal? Justify your answer.

Suppose that u and v are two non-orthogonal vectors in an inner product space V,< ,...

Suppose that u and v are two non-orthogonal vectors in an inner product space V,< , >. Question 2: Can we modify the inner product < , > to a new inner product so that the two vectors become orthogonal? Justify your answer.

Question 4. Consider the following subsets of the vector space P3 of polynomials of degree 3...

Question 4. Consider the following subsets of the vector space P3 of polynomials of degree 3 or less: S = {p(x) : p(1) = 0} and T = {q(x) : q(0) = 1} Determine if these subsets are vectors spaces with the standard operations for polynomials

Suppose V is a finite dimensional inner product space. Prove that every orthogonal operator on V...

Suppose V is a finite dimensional inner product space. Prove that every orthogonal operator on V , i.e. <T(u), T(v)> , ∀u,v ∈ V , is an isomorphism.

Let V be an inner product space. Prove that if w⃗ is orthogonal to each of...

Let V be an inner product space. Prove that if w⃗ is orthogonal to each of the vectors in the set S = {⃗v1, ⃗v2, . . . , ⃗vm}, then w⃗ is also orthogonal to each of the vectors in the subspace W = SpanS of V .