Give an example of a linear transformation T:R2 -->R2 such that rank(T)=rank(T2) and T does not...

(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...

Give an example of the described object or explain why such an example does not exist....

Give an example of the described object or explain why such an example does not exist. •An orthogonal linear transformation T: R2→R2. •An orthogonal linear transformation T: R3→R3. •A basis B for R2 and an orthogonal linear transformation T: R2→R2 such that [T]B is an orthogonal matrix. •A basis B for R2 and an orthogonal linear transformation T: R2→R2 such that [T]B is NOT an orthogonal matrix. •A non-orthogonal linear transformation that takes an orthogonal basis to an orthogonal basis.

Determine whether or not the transformation T is linear. If the transformation is linear, find the...

Determine whether or not the transformation T is linear. If the transformation is linear, find the associated representation matrix (with respect to the standard basis). (a) T ( x , y ) = ( y , x + 2 ) (b) T ( x , y ) = ( x + y , 0 )

Let T be the linear transformation from R2 to R2, that rotates a vector clockwise by...

Let T be the linear transformation from R2 to R2, that rotates a vector clockwise by 60◦ about the origin, then reflects it about the line y = x, and then reflects it about the x-axis. a) Find the standard matrix of the linear transformation T. b) Determine if the transformation T is invertible. Give detailed explanation. If T is invertible, find the standard matrix of the inverse transformation T−1. Please show all steps clearly so I can follow your...

3. Find the linear transformation T : R2 → R2 described geometrically by “first rotate coun-...

3. Find the linear transformation T : R2 → R2 described geometrically by “first rotate coun- terclockwise by 60◦, then reflect across the line y = x, then scale vectors by a factor of 5”. Is this linear transformation invertible? If so, find the matrix of the inverse transformation.

3.) Find the linear transformation T : R2 to R2 described geometrically by "first rotate counter-clockwise...

3.) Find the linear transformation T : R2 to R2 described geometrically by "first rotate counter-clockwise by 60 degrees, then reflect across the line y = x, then scale vectors by a factor of 5". Is this linear transformation invertible? If so, find the matrix of the inverse transformation.

Let A equal the 2x2 matrix: [1 -2] [2 -1] and let T=LA R2->R2. (Notice that...

Let A equal the 2x2 matrix: [1 -2] [2 -1] and let T=LA R2->R2. (Notice that this means T(x,y)=(x-2y,2x-y), and that the matrix representation of T with respect to the standard basis is A.) a. Find the matrix representation [T]BB where B={(1,1),(-1,1)} b. Find an invertible 2x2 matrix Q so that [T]B = Q-1AQ

(a) Let T be any linear transformation from R2 to R2 and v be any vector...

(a) Let T be any linear transformation from R2 to R2 and v be any vector in R2 such that T(2v) = T(3v) = 0. Determine whether the following is true or false, and explain why: (i) v = 0, (ii) T(v) = 0. (b) Find the matrix associated to the geometric transformation on R2 that first reflects over the y-axis and then contracts in the y-direction by a factor of 1/3 and expands in the x direction by a...

Does there exist a linear transformation T from R2 to R3 that is onto but not...

Does there exist a linear transformation T from R2 to R3 that is onto but not 1-1? Support your answer with a proof or counterexample, as appropriate.

10 Linear Transformations. Let V = R2 and W = R3. Define T: V → W...

10 Linear Transformations. Let V = R2 and W = R3. Define T: V → W by T(x1, x2) = (x1 − x2, x1, x2). Find the matrix representation of T using the standard bases in both V and W 11 Let T :R3 →R3 be a linear transformation such that T(1, 0, 0) = (2, 4, −1), T(0, 1, 0) = (1, 3, −2), T(0, 0, 1) = (0, −2, 2). Compute T(−2, 4, −1).