For an arbitrary m x n matrix, Prove that (AT)T = A by using the definition...

Let A be an n x M matrix and let T(x) =A(x). Prove that T: R^m...

Let A be an n x M matrix and let T(x) =A(x). Prove that T: R^m R^n is a linear transformation

n×n-matrix M is symmetric if M = M^t. Matrix M is anti-symmetric if M^t = -M....

n×n-matrix M is symmetric if M = M^t. Matrix M is anti-symmetric if M^t = -M. 1. Show that the diagonal of an anti-symmetric matrix are zero 2. suppose that A,B are symmetric n × n-matrices. Prove that AB is symmetric if AB = BA. 3. Let A be any n×n-matrix. Prove that A+A^t is symmetric and A - A^t antisymmetric. 4. Prove that every n × n-matrix can be written as the sum of a symmetric and anti-symmetric matrix.

Prove the following: Given k x m matrix A, m x n matrix B. Then rank(A)=m...

Prove the following: Given k x m matrix A, m x n matrix B. Then rank(A)=m --> rank(AB)=rank(B)

Prove that for a matrix A(m*n): rankA + NullityA = n

Prove that for a matrix A(m*n): rankA + NullityA = n

Prove that any m ×n matrix A can be written in the form A = QR,...

Prove that any m ×n matrix A can be written in the form A = QR, where Q is an m × m orthogonal matrix and R is an m × n upper right triangular matrix.

Prove the Cayley-Hamilton theorem for any n x n square matrix.

Prove the Cayley-Hamilton theorem for any n x n square matrix.

Using the definition (must show the calculation) prove that the Laplace transform of e^t t is...

Using the definition (must show the calculation) prove that the Laplace transform of e^t t is 1/(s-1)^2

Let E be an n×n matrix, and letU= {xE:x∈Rn} (where x∈Rn is written as arow vector)....

Let E be an n×n matrix, and letU= {xE:x∈Rn} (where x∈Rn is written as arow vector). Show that the following are equivalent. (a) E^2 = E = E^T (T means transpose). (b) (u − uE) · (vE) = 0 for all u, v ∈ Rn. (c) projU(v) = vE for all v ∈ Rn.

1. If A is an n n matrix, prove that (a) ATA is a symmetric matrix....

1. If A is an n n matrix, prove that (a) ATA is a symmetric matrix. (b) A + AT is a symmetric matrix and A - AT is a skew-symmetric matrix. (c) A is the sum of a symmetric and a skew-symmetric matrix.

1. Using the definition of Θ, prove that if f(n) ∈ Θ(g(n)), then g(n) ∈ Θ(f(n)).

1. Using the definition of Θ, prove that if f(n) ∈ Θ(g(n)), then g(n) ∈ Θ(f(n)).