Deck 5: Determinants

Find
and
for the matrix

Find
and
for the matrix

Find
and
for the matrix

Use the Shortcut Method to find the determinant of the matrix

Find all values of a such that the matrix A is not invertible.

Determine all real values of λ such that
for the matrix

Determine all real values of
such that
for the matrix

Evaluate

,

,

, and
where

Evaluate

,

,

, and
where

​

Let A and B be
matrices. Then

.

Let A be a
matrix. Then

.

If A is a square matrix, and

, then A is invertible.

If A is a
matrix and
is a scalar, then

.

If A is a
matrix, and B is an
matrix, then

.

Compute the determinant of the given matrix A by using row operations to reduce to echelon form.

Compute the determinant of the given matrix A by using row operations to reduce to echelon form.

Compute the determinant of the given matrix A by using row operations to reduce to echelon form.

Suppose the matrix

results from a matrix A using the row operations
and

. Find

.

Suppose the matrix

results from a matrix A using the row operations

,

,

, and

. Find

.

Suppose A, B, and C are
matrices and

,

, and

. Find each of the following.(a)
(b)
(c)
(d)

Partition matrix A to evaluate

, where

Partition matrix A to evaluate

, where

Use determinants to decide if a unique solution exists for the linear system

Use determinants to decide if a unique solution exists for the linear system

If a
matrix B is obtained from a matrix A by multiplying every row of A by

, then

.

If

, then at least one entry of A has value

.

If A and B are square matrices, and

, then either
or

.

If A is invertible, then

.

If A, B, C, and D are square matrices of the same size, then

.

A square matrix
is called nilpotent if
for some positive integer k. Prove that if
is nilpotent, then

.

If applicable, use Cramer's Rule to find the unique solution of the given linear system. If Cramer's Rule is not applicable, explain why.

If applicable, use Cramer's Rule to find the unique solution of the given linear system. If Cramer's Rule is not applicable, explain why.

Without solving for

, use Cramer's Rule to find the value of
in the linear system.

Without solving for

, use Cramer's Rule to find the value of
in the linear system.

Find
and use it to determine

, where

Find
and use it to determine

, where

Use determinants to find the area of the parallelogram with vertices (0, 0), (3, 2), (2, 3), and (-1, 1).

Use determinants to find the area of the parallelogram with vertices (4, 1), (6, -1), (4, 0), and (6, 0).

Find the area of T (D) where

, D is the rectangle with vertices (0, 0), (4, 0), (4, -1), and (0, -1), and

Find the area of T (D) where

, D is the parallelogram with vertices (4, 2), (5, 3), (4, 6), and (3, 5), and

For all
matrices A,

.

For all
matrices A,

.

For all
matrices A,

.

If

, then

.

.

If A is an invertible matrix, then
is invertible, and

.

If A is a square matrix and

, then A is a diagonal matrix.