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

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.

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 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 .

Suppose 〈 , 〉 is an inner product on a vector space V . Show that...

Suppose 〈 , 〉 is an inner product on a vector space V . Show that no vectors u and v exist such that ∥u∥ = 1, ∥v∥ = 2, and 〈u, v〉 = −3.

3. a. Consider R^2 with the Euclidean inner product (i.e. dot product). Let v = (x1,...

3. a. Consider R^2 with the Euclidean inner product (i.e. dot product). Let v = (x1, x2) ? R^2. Show that (x2, ?x1) is orthogonal to v. b. Find all vectors (x, y, z) ? R^3 that are orthogonal (with the Euclidean inner product, i.e. dot product) to both (1, 3, ?2) and (2, 7, 5). C.Let V be an inner product space. Suppose u is orthogonal to both v and w. Prove that for any scalars c and d,...

let v be an inner product space with an inner product(u,v) prove that ||u+v||<=||u||+||v||, ||w||^2=(w,w) ,...

let v be an inner product space with an inner product(u,v) prove that ||u+v||<=||u||+||v||, ||w||^2=(w,w) , for all u,v load to V. hint : you may use the Cauchy-Schwars inquality: |{u,v}|,= ||u||*||v||.

(uxv) is orthogonal to (u+v) and (u-v) u and v are nonzero vectors not sure where...

(uxv) is orthogonal to (u+v) and (u-v) u and v are nonzero vectors not sure where to go from this I do the cross product of uxv...what do i do for u+v and u-v?? is it a dot product?

1) If u and v are orthogonal unit vectors, under what condition au+bv is orthogonal to...

1) If u and v are orthogonal unit vectors, under what condition au+bv is orthogonal to cu+dv (where a, b, c, d are scalars)? What are the lengths of those vectors (express them using a, b, c, d)? 2) Given two vectors u and v that are not orthogonal, prove that w=‖u‖2v−uuT v is orthogonal to u, where ‖x‖ is the L^2 norm of x.

Suppose u, and v are vectors in R m, such that ∥u∥ = 1, ∥v∥ =...

Suppose u, and v are vectors in R m, such that ∥u∥ = 1, ∥v∥ = 4, ∥u + v∥ = 5. Find the inner product 〈u, v〉. (b) Suppose {a1, · · · ak} are orthonormal vectors in R m. Show that {a1, · · · ak} is a linearly independent set