Define T: R3 → P2(R) by T(aj, az, az) = (a1 + a2 + az) + (a1 + a2 + a3x + 21x2. Determine if T is invertible and compute the inverse of T if it exists.
Let V P2(R) and let T V-V be a linear transformation defined by T(p)-q, where (x)(r p (r Let B = {x, 1 + x2, 2x-1} be a basis of V. Compute [TIB,B, and deduce if it is eigenvectors basis of
R is defined by T (7) = AZ mation T: R3 4. [20 marks) A linear transformation T: R with A given as follows: A= [ 1 -2 1 3 0 -21 1 6 -2 -5 J (1). (8 marks) A vector in R is given as follows = -1 determine the image of 7 under T. 12 marks) Find a vector in Rwhose image under T is the following vector 6 -17 7 = 7 L -3 or demonstrate...
Consider the inner product space V = P2(R) with (5,9) = { $(0)g(t) dt, and let T:VV be the linear operator defined by T(f) = x f'(x) +2f (x) +1. (i) Compute T*(1 + x + x2). (ii) Determine whether or not there is an orthonormal basis of eigenvectors ß for which [T]k is diagonal. If such a basis exists, find one.
a. 6. Let T: R* → P2(R)be defined as T 2) = (a - 2d) + (c + 3b)x + (a - 2c)x Ld] I Find a basis for the Ker(T). (3pts) b. Find a basis for the Range(T) (3pts) c. Determine whether T is one-to-one. (2pts) d. Determine whether T is onto. (2pts)
Let V = P1(R) and W = R2. Let B = (1,x) and y=((1,0), (0, 1)) be the standard ordered bases for V and W respectively. Define a linear map T:V + W by T(P(x)) = (p(0) – 2p(1), p(0) + p'(0)). (a) Let FEW* be defined by f(a,b) = a – 26. Compute T*(f). (b) Compute [T]y,ß and (T*]*,y* using the definition of the matrix of a linear transformation.
Let x = [xı x2 x3], and let TER → R be the linear transformation defined by T() = x1 + 6x2 – x3 -X2 X1 + 4x3 Let B be the standard basis for R2 and let B' = {V1, V2, V3}, where 7 7 and v3 = 7 V1 V2 [] --[] 0 Find the matrix of I with respect to the basis B. and then use Theorem 8.5.2 to compute the matrix of T with respect to...
2. Consider the inner product space V = P2(R) with (5,9) = . - f(t)g(t) dt, and let T:V + V be the linear operator defined by T(F) = xf'(x) + 2f (x). (i) Compute T*(1 + x + x2). (ii) Determine whether or not there is an orthonormal basis of eigenvectors ß for which [T]2 is diagonal. If such a basis exists, find one.
3. Let T : P2(R) → P2(R) be defined by T(f(x)) = f'(x). Find an element v ∈ P2(R) such that v, T v, T^2 v is a basis of generalized eigenvectors of T.
1 #6: Let T: P2 → p2 be defined by T(ao +ajx + a2 x2) = (Tao + 381 +8a2) – (a1 + 36a2)x+ 20 x2 Find the eigenvalues of T. Enter any repeated eigenvalues as often as they repeat. em #6: