Find the matrix [T], p of the linear transformation T: V - W with respect to...
Find the matrix [T] C-B of the linear transformation T: VW with respect to the bases B and C of V and w, respectively. T: R2 + R3 defined by a + 2b -a b +[:] s={{ ;][-:} c-{{0}{} --13) [) CBT
Problem 3. Let V and W be vector spaces of dimensions n and m, respectively, and let T : V -> W be a linear transformation. (a) Prove that for every pair of ordered bases B = exists a unique m x n matrix A such that [T(E)]c = A[r3 for all e V. The matrix A is called the (B,C)-matrix of T, written A = c[T]b. (b) For each n E N, let Pm be the vector space of...
Problem 3. Let V and W be vector spaces of dimensions n and m, respectively, and let T : V -> V be a linear transformation (a) Prove that for every pair of ordered bases B = (Ti,...,T,) of V and C = (Wi, ..., Wm) of W, then exists a unique (B, C)-matrix of T, written A = c[T]g. (b) For each n e N, let Pn be the vector space of polynomials of degree at mostn in the...
7. Let T : V → W be a linear transformation, and let v1,v2,...,vn be vectors in V. Suppose that T (v1), T (v2), . . . , T (vn) are linearly independent. Show that v1, v2, . . . , vn are linearly independent.
THEOREM 3.4. Suppose T: V -» W is a linear transformation from K-linear spaces V to W. Then (a) ker(T) is a subspace of V, and (b) im(T) is a subspace of W PROOF. The proof is left as an exercise.
2. Choose either of them. In each of the following problems, W (a). Find the matrix M of the linear transformation T: V relative to the bases B and C of V and W, respectively. (b). A vector in V is given, verify that (T(7)]c = M(7)B (1). A linear transformation T: P2 R is defined by T (PU) - ( PC ), i.e., 7(a + bé + caº) = [atőte] B = {2,1,1}, c= {{0}][1]} p(t) = 1 +...
Find the matrix of the linear transformation T: V →W relative to B and C. Suppose B = {bı, b2, b3} is a basis for V and C = {C1, C2} is a basis for W. Let T be defined by T(b]) = 261 + C2 T(62) = -501 +502 T(b3) = 2C1-802 2. 3 0 2 -6 [3 0 -6 1 5-8 2 -5 2 5 -8 2 1 -5 5 2 -8
know how to find the matrix representation [T]5 for a linear transforma- tion T V W with respect to bases a, B for V, W, respectively. know how to use the matrix representation [T5 and the coordinate map- pings R of T W to find bases for the kernel and image V, :Rm -> given two bases a, from a coordinates to 3 coordinates for Rn, know how to find the change of basis matrix know how to find the...
show all parts and explain - For each linear transformation f :V W, find the associated matrix. W with given bases for V and (a) tr : M22 → R (trace of a matrix) with R-basis {1} and M22-basis (19):( :) :( 9):( )} (b) E: P2 → R2 which sends f e P, to [f( 1), f(2)] € R2, and the standard bases. (c) Given some basis B = {81,...,Bn} of V, the linear transforma- tion C: V →...
3. This example hopes to illustrate why the vector spaces the linear transformation are defined on are critical to the question of invertibility. Let L : → p, be defined by L(p)(t+1)p(t)-plt). (a) Given a basis of your choice, find a matrix representation of I with respect to your chosen basis (b) Show L: P+P is not invertible (e) Let V-span+21-4,+2t-8). It can be shown that L VV. Given an ordered basis for V of your choice, find a matrix...