Suppose S and T are endomorphisms of V and γ:V→W is an isomorphism such thatγ◦T◦γ−1 and...

Let N be a nilpotent mapping V and letγ:V→V be an isomorphism. 1.Show that N and...

Let N be a nilpotent mapping V and letγ:V→V be an isomorphism. 1.Show that N and γ◦N◦γ−1 have the same canonical form 2. If M is another nilpotent mapping of V such that N and M have the same canonical form, show that there is an isomorphism γ such that γ◦N◦γ−1=M

1.a Implication: If an endomorphism f : V → V is not an isomorphism, then it...

1.a Implication: If an endomorphism f : V → V is not an isomorphism, then it must have a non-trivial kernel. Use this implication, together with the definition of determinant given in class, to show that if for an endomorphism f : V → V we have det(f) 6 /= 0, then in fact f is an isomorphism. 1.b. The Rank-Nullity Theorem applies to a linear map f : V → W (where V is finite dimensional) and claims that:...

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.

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 .

Suppose that V is a vector space with basis {u, v, w}. Suppose that T is...

Suppose that V is a vector space with basis {u, v, w}. Suppose that T is a linear transformation from V to W and suppose also that {T(u), T(v), T(w)} is a basis for W. Prove from the definitions that T is both 1-1 and onto.

Construct a linear transformation T : V → W, where V and W are vector spaces...

Construct a linear transformation T : V → W, where V and W are vector spaces over F such that the dimension of the kernel space of T is 666. Is such a transformation unique? Give reasons for your answer.

True or False? No reasons needed. (e) Suppose β and γ are bases of F n...

True or False? No reasons needed. (e) Suppose β and γ are bases of F n and F m, respectively. Every m × n matrix A is equal to [T] γ β for some linear transformation T: F n → F m. (f) Recall that P(R) is the vector space of all polynomials with coefficients in R. If a linear transformation T: P(R) → P(R) is one-to-one, then T is also onto. (g) The vector spaces R 5 and P4(R)...

Suppose T : V → W is a homomorphism. Prove: (i) If dim(V ) < dim(W)...

Suppose T : V → W is a homomorphism. Prove: (i) If dim(V ) < dim(W) then T is not surjective. (ii) If dim(V ) > dim(W) then T is not injective.

Let V be a three-dimensional vector space with ordered basis B = {u, v, w}. Suppose...

Let V be a three-dimensional vector space with ordered basis B = {u, v, w}. Suppose that T is a linear transformation from V to itself and T(u) = u + v, T(v) = u, T(w) = v. 1. Find the matrix of T relative to the ordered basis B. 2. A typical element of V looks like au + bv + cw, where a, b and c are scalars. Find T(au + bv + cw). Now that you know...

Problem 3. Recall that a linear map f : V → W is called an isomorphism...

Problem 3. Recall that a linear map f : V → W is called an isomorphism if it is invertible (i.e. has a linear inverse map). We proved in class that f is in fact invertible if and only if it is bijective. Use this fact from class together with the Rank-Nullity Theorem (of the previous problem) to show that if f : V → V is an endomorphism, then it is actually invertible if 1. it is merely injective...