A matrix A is orthogonal if ATA = I. Show that if A is orthogonal and C is the cofactor matrix of A, then C equals either A or -A. 

Suppose A is an orthogonal matrix. Show that |λ| = 1 for all eigen- values λ....

Suppose A is an orthogonal matrix. Show that |λ| = 1 for all eigen- values λ. (Hint: start off with an eigenvector and dot-product it with itself. Then cleverly insert A and At into the dot-product.) b) Suppose P is an orthogonal projection. Show that the only possible eigenvalues are 0 and 1. (Hint: start off with an eigenvector and write down the definition. Then apply P to both sides.) An n×n matrix B is symmetric if B = Bt....

Let Q(t) be a matrix, function of time, t. Assume that Q is orthogonal for all...

Let Q(t) be a matrix, function of time, t. Assume that Q is orthogonal for all t. Show that if Q(t_0) = I (identity matrix) for some t_0 then d/dt (Q(t_0)) is skew-symmetric.

Suppose is orthogonal to vectors and . Show that is orthogonal to every in the span...

Suppose is orthogonal to vectors and . Show that is orthogonal to every in the span {u,v}. [Hint: An Arbitrary w in Span {u,v} has the form w=c1u+c2v. Show that y is orthogonal to such a vector w.] What theorem can I use for this?

(3 pts) Let A be a square n × n matrix whose rows are orthogonal. Prove...

(3 pts) Let A be a square n × n matrix whose rows are orthogonal. Prove that the columns of A are also orthogonal. Hint: The orthogonality of rows is equivalent to AAT = I ⇒ ATAAT = AT

show that a real 2x2 matrix is normal if and only if it is either symmetric...

show that a real 2x2 matrix is normal if and only if it is either symmetric or has the form a b -b a (in matrix form)

This is a TRUE-FALSE Question with justification. If Q is an orthogonal n×n matrix, then Row(Q)...

This is a TRUE-FALSE Question with justification. If Q is an orthogonal n×n matrix, then Row(Q) = Col(Q). The Answer to this is TRUE. I want to know a solid reasoning/explanation for it. In one of the answers, it says that " Since Q is orthogonal, QTQ = I, so Q is invertible, hence Row(Q) = Col(Q) = Rn. But my question is: Why is it that for an invertible matrix, Row(Q) = Col (Q) ? Any other explanation that...

9. Either give an example of each of the following or explain why it would be...

9. Either give an example of each of the following or explain why it would be impossible. (a) [2 points] Two orthogonal vectors in R 3 that are linearly dependent. (b) [2 points] Three orthonormal vectors in R 3 that are linearly dependent. (c) [2 points] A 3 × 2 matrix Q whose column vectors are orthonormal and QQT 6= I. (d) [2 points] A 3 × 3 matrix Q whose column vectors are orthonormal and QQT 6= I. (e)...

A matrix A is called orthonormal if AAT = I. (a) Show that an orthonormal matrix...

A matrix A is called orthonormal if AAT = I. (a) Show that an orthonormal matrix is invertible and that the inverse is orthonormal. (b) Showtheproductoftwoorthonormalmatricesisalsoorthonormal. (c) By trials and errors, nd three orthonormal matrices of order 2. (d) Let x be a real number, show that the matrices A =cosx −sinx sinx cosx, B = cosx sinx −sinx cosx are orthonormal.

1. Find the orthogonal projection of the matrix [[3,2][4,5]] onto the space of diagonal 2x2 matrices...

1. Find the orthogonal projection of the matrix [[3,2][4,5]] onto the space of diagonal 2x2 matrices of the form lambda?I.   [[4.5,0][0,4.5]]  [[5.5,0][0,5.5]]  [[4,0][0,4]]  [[3.5,0][0,3.5]]  [[5,0][0,5]]  [[1.5,0][0,1.5]] 2. Find the orthogonal projection of the matrix [[2,1][2,6]] onto the space of symmetric 2x2 matrices of trace 0.   [[-1,3][3,1]]  [[1.5,1][1,-1.5]]  [[0,4][4,0]]  [[3,3.5][3.5,-3]]  [[0,1.5][1.5,0]]  [[-2,1.5][1.5,2]]  [[0.5,4.5][4.5,-0.5]]  [[-1,6][6,1]]  [[0,3.5][3.5,0]]  [[-1.5,3.5][3.5,1.5]] 3. Find the orthogonal projection of the matrix [[1,5][1,2]] onto the space of anti-symmetric 2x2 matrices.   [[0,-1] [1,0]]  [[0,2] [-2,0]]  [[0,-1.5] [1.5,0]]  [[0,2.5] [-2.5,0]]  [[0,0] [0,0]]  [[0,-0.5] [0.5,0]]  [[0,1] [-1,0]] [[0,1.5] [-1.5,0]]  [[0,-2.5] [2.5,0]]  [[0,0.5] [-0.5,0]] 4. Let p be the orthogonal projection of u=[40,-9,91]T onto the...

1). Show that if AB = I (where I is the identity matrix) then A is...

1). Show that if AB = I (where I is the identity matrix) then A is non-singular and B is non-singular (both A and B are nxn matrices) 2). Given that det(A) = 3 and det(B) = 2, Evaluate (numerical answer) each of the following or state that it’s not possible to determine the value. a) det(A^2) b) det(A’) (transpose determinant) c) det(A+B) d) det(A^-1) (inverse determinant)