Express (BC)∗ , where B and C are nxn matrices.

Characterize the family of all nxn non singular matrices A for which one step of the...

Characterize the family of all nxn non singular matrices A for which one step of the Gauss- Seidel algorithm solves Ax=b starting at the vector x=0

D, E are symmetric, real nxn matrices. D is positive definite. E is positive semidefinite. What...

D, E are symmetric, real nxn matrices. D is positive definite. E is positive semidefinite. What is the definiteness of D+E?

If A and B are two real matrices where A∗B is non-singular, then can it be...

If A and B are two real matrices where A∗B is non-singular, then can it be assumed that both A and B are non-singular? (Could A and B be non-square?)

Prove that given △ABC and △A′B′C′, if we have AB ≡ A′B′ and BC≡B′C′,then B<B′ if...

Prove that given △ABC and △A′B′C′, if we have AB ≡ A′B′ and BC≡B′C′,then B<B′ if and only if AC<A′C′. You cannot use measures.

If A, B, and C are 4x4 matrices; and det(A) = 1, det(B) = -5, and...

If A, B, and C are 4x4 matrices; and det(A) = 1, det(B) = -5, and det(C) = -3, then compute: det(4B3A-1C-1A-1B2) = ____

a.) What is a "tanspose" b.) If A, B, C, and D are the matrices below,...

a.) What is a "tanspose" b.) If A, B, C, and D are the matrices below, which of the sums A + B, B + C, and C + D are defined? Explain A = [ 1 B = [ 3 4] C = [ 1 2 D = [ 1 -1 2 ] 3 4 ] 0 1 ]

Prove: P(A ∪ B ∪ C) = P(A) + P(Ac ∩ B) + P(Ac ∩ Bc...

Prove: P(A ∪ B ∪ C) = P(A) + P(Ac ∩ B) + P(Ac ∩ Bc ∩ C)

Let A, B, and C be n×n matrices of the form A= [c_1...x...c_n], B= [c_1...y...c_n], and...

Let A, B, and C be n×n matrices of the form A= [c_1...x...c_n], B= [c_1...y...c_n], and C= [c_1...x+y...c_n] where x, y, and x+y are the jth column vectors. Use cofactor expansions to prove that det(C)=det(A)+det(B).

Let A and B be n x n matrices and c be a scalar. Prove that,...

Let A and B be n x n matrices and c be a scalar. Prove that, if B is obtained by muliplying a row of A by c, then |B|= c|A|.

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)