Let U and V be vector spaces. Show that the Cartesian product U × V =...

Let U be a vector space and V a subspace of U. (a) Assume dim(U) <...

Let U be a vector space and V a subspace of U. (a) Assume dim(U) < ∞. Show that if dim(V ) = dim(U) then V = U. (b) Assume dim(U) = ∞ and dim(V ) = ∞. Give an example to show that it may happen that V 6= U.

1. Let T be a linear transformation from vector spaces V to W. a. Suppose that...

1. Let T be a linear transformation from vector spaces V to W. a. Suppose that U is a subspace of V, and let T(U) be the set of all vectors w in W such that T(v) = w for some v in V. Show that T(U) is a subspace of W. b. Suppose that dimension of U is n. Show that the dimension of T(U) is less than or equal to n.

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.

Let L : V → W be a linear transformation between two vector spaces. Show that...

Let L : V → W be a linear transformation between two vector spaces. Show that dim(ker(L)) + dim(Im(L)) = dim(V)

Let S, U, and W be subspaces of a vector space V, where U ⊆ W....

Let S, U, and W be subspaces of a vector space V, where U ⊆ W. Show that U + (W ∩ S) = W ∩ (U + S)

Let S={u,v,w}S={u,v,w} be a linearly independent set in a vector space V. Prove that the set...

Let S={u,v,w}S={u,v,w} be a linearly independent set in a vector space V. Prove that the set S′={3u−w,v+w,−2w}S′={3u−w,v+w,−2w} is also a linearly independent set in V.

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.

Let U and V be subspaces of the vector space W . Recall that U ∩...

Let U and V be subspaces of the vector space W . Recall that U ∩ V is the set of all vectors ⃗v in W that are in both of U or V , and that U ∪ V is the set of all vectors ⃗v in W that are in at least one of U or V i: Prove: U ∩V is a subspace of W. ii: Consider the statement: “U ∪ V is a subspace of W...

Let (V, |· |v ) and (W, |· |w ) be normed vector spaces. Let T...

Let (V, |· |v ) and (W, |· |w ) be normed vector spaces. Let T : V → W be linear map. The kernel of T, denoted ker(T), is defined to be the set ker(T) = {v ∈ V : T(v) = 0}. Then ker(T) is a linear subspace of V . Let W be a closed subspace of V with W not equal to V . Prove that W is nowhere dense in V .