Show that U = {T : R2 → R2: T is linear and is NOT injective.}...

Let T:V→W be a linear transformation and U be a subspace of V. Let T(U)T(U) denote...

Let T:V→W be a linear transformation and U be a subspace of V. Let T(U)T(U) denote the image of U under T (i.e., T(U)={T(u⃗ ):u⃗ ∈U}). Prove that T(U) is a subspace of W

Let T: U--> V be a linear transformation. Prove that the range of T is a...

Let T: U--> V be a linear transformation. Prove that the range of T is a subspace of W

Consider the Mapping T: R2 -->P1 where T(a,b) = (a-b)x + 2a Find Ker(T) Show that...

Consider the Mapping T: R2 -->P1 where T(a,b) = (a-b)x + 2a Find Ker(T) Show that T is injective and subjective.

Let T ∈ L(R2) be the linear transformation T(x1, x2) = (3x1 + 2x2, −4x1 −...

Let T ∈ L(R2) be the linear transformation T(x1, x2) = (3x1 + 2x2, −4x1 − 3x2), v = (1, −1), and p(z) = z^2 − 3z + 2. Compute p(T), show that p(T)v = 0, and show that NOT all the roots of p(z) are eigenvalues of T.

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.

1. Consider the set U={(x,y) in R2| -1<x<1 and y=0}. Is U open in R2? Is...

1. Consider the set U={(x,y) in R2| -1<x<1 and y=0}. Is U open in R2? Is it open in R1? Is it open as a subspace of the disk D={(x,y) in R2 | x^2+y^2<1} ? 2. Is there any subset of the plane in which a single point set is open in the subspace topology?

a. Let T : V → W be left invertible. Show that T is injective. b....

a. Let T : V → W be left invertible. Show that T is injective. b. Let T : V → W be right invertible. Show that T is surjective

Suppose that V is finite-dimensional, U ⊂ V is a subspace, and S : U →...

Suppose that V is finite-dimensional, U ⊂ V is a subspace, and S : U → W is a linear map. Show that there exists a linear map T : V → W such that T u = Su for every u ∈ U.

(12) (after 3.3) (a) Find a linear transformation T : R2 → R2 such that T...

(12) (after 3.3) (a) Find a linear transformation T : R2 → R2 such that T (x) = Ax that reflects a vector (x1, x2) about the x2-axis. (b) Find a linear transformation S : R2 → R2 such that T(x) = Bx that rotates a vector (x1, x2) counterclockwise by 135 degrees. (c) Find a linear transformation (with domain and codomain) that has the effect of first reflecting as in (a) and then rotating as in (b). Give the...

(a) Prove that if two linear transformations T,U : V --> W have the same values...

(a) Prove that if two linear transformations T,U : V --> W have the same values on a basis for V, i.e., T(x) = U(x) for all x belong to beta , then T = U. Conclude that every linear transformation is uniquely determined by the images of basis vectors. (b) (7 points) Determine the linear transformation T : P1(R) --> P2(R) given by T (1 + x) = 1+x^2, T(1- x) = x by finding the image T(a+bx) of...