Deck 6: Eigenvalues and Eigenvectors

Determine which of , , and are eigenvectors of
,
and determine the associated eigenvalues.

Find a basis for the eigenspace associated with eigenvalue for matrix
.

Find a basis for the eigenspace associated with eigenvalue for matrix
.

Find a basis for the eigenspace associated with eigenvalue for the matrix

.

Find the characteristic polynomial, the eigenvalues, and a basis for each eigenspace for the matrix A =
.

Find the characteristic polynomial, the eigenvalues, and a basis for each eigenspace for the matrix A =
.

Find the characteristic polynomial, the eigenvalues, and a basis for each eigenspace for the matrix A =
.

Find the characteristic polynomial, the eigenvalues, and a basis for each eigenspace for the matrix A =
.

Find the characteristic polynomial, the eigenvalues, and a basis for each eigenspace for the matrix A =
.

An matrix A can have no more than n eigenvalues.

If is the characteristic polynomial of an matrix A, and , then A is not invertible.

Suppose the matrix A has n distinct eigenvalues. Then the dimension of each eigenspace is 1.

If u and v are both eigenvectors of an n ×n matrix A, then u+v is also an eigenvector of the A.

If is an eigenvalue of an invertible matrix A, then is an eigenvalue of the matrix
.

Compute if
.

Compute if
.

Find the matrix A that has the given eigenvalues and corresponding eigenvectors.

Find the matrix A that has the given eigenvalues and bases for the corresponding eigenspaces.

;
;

Find the matrix A that has the given eigenvalues and bases for the corresponding eigenspaces.

Diagonalize the matrix A, if possible.

Diagonalize the matrix A, if possible.

Diagonalize the matrix A, if possible.

Diagonalize the given matrix A, and use the diagonalization to compute
.

Diagonalize the given matrix A, and use the diagonalization to compute
.

If an matrix A has n distinct eigenvalues, then A is diagonalizable.

The matrix is diagonalizable.

If A and are diagonalizable matrices, then AB is diagonalizable.

If and , where , and and are nonzero vectors, then is linearly independent.

If A is diagonalizable, then is diagonalizable.

Find the eigenvalues and a basis for each eigenspace for the given matrix.

Find the eigenvalues and a basis for each eigenspace for the given matrix.

Find the eigenvalues and a basis for each eigenspace for the given matrix.

Find the eigenvalues and a basis for each eigenspace for the given matrix.

Determine the rotation and dilation that result from multiplying vectors in by the given matrix.

Determine the rotation and dilation that result from multiplying vectors in by the given matrix.

Find the rotation-dilation matrix B within the given matrix A.

Find the rotation-dilation matrix B within the given matrix A.

Factor the matrix from Question 1 in the form where B is a rotation-dilation matrix.

Factor the matrix from Question 2 in the form where B is a rotation-dilation matrix.

Factor the given matrix A in the form where B is a rotation-dilation matrix. Find the dilation and angle of rotation. Use this information to evaluate the matrix power without computing it directly.

If A is a real matrix, and is a complex eigenvalue of A, then is also an eigenvalue of A.

If A is a real matrix and is an eigenvalue of A with and corresponding eigenvector u, then
.

If the invertible matrix A has hidden rotation-dilation matrix , where then has hidden rotation-dilation matrix
.

If is an eigenvalue of the real matrix A with corresponding eigenvector , then is an eigenvalue of with corresponding eigenvector
.

The coefficient matrix for a system of linear differential equations of the form has the given eigenvalues and eigenspace bases. Find the general solution for the system.

The coefficient matrix for a system of linear differential equations of the form has the given eigenvalues and eigenspace bases. Find the general solution for the system.

The coefficient matrix for a system of linear differential equations of the form has the given eigenvalues and eigenspace bases. Find the general solution for the system.

The coefficient matrix for a system of linear differential equations of the form has the given eigenvalues and eigenspace bases. Find the general solution for the system.

The coefficient matrix for a system of linear differential equations of the form has the given eigenvalues and eigenspace bases. Find the general solution for the system.

The coefficient matrix for a system of linear differential equations of the form has the given eigenvalues and eigenspace bases. Find the general solution for the system.

Find the general solution for the system
.

Find the general solution for the system
.

Find the solution for the system that satisfies the condition at t = 0.

Find the solution for the system that satisfies the condition at t = 0.​

Suppose that two countries are in an arms race modeled by the system of differential equations

where y₁ and y₂ are measured in thousands. Find the solution for the system with initial conditions , and use it to predict the long-term amounts of arms held by each country.

If , and are solutions to the initial-value problem , with , then for all t.

If A is a real square matrix with complex eigenvalue and associated eigenvector , then is a real solution to the system
.

Suppose that A is an matrix and is a solution to the system of linear differential equations where is an eigenvector of A with associated eigenvalue
. Let k be any scalar. Then is a solution to the system
.

Suppose that A is an matrix and is a solution to the system of linear differential equations where is an eigenvector of A with associated eigenvalue
. If A is invertible, then is a solution to the system
.

Compute the first three iterations of the Power Method without scaling, starting with the given , where
.

Compute the first three iterations of the Power Method without scaling, starting with the given , where
.

Compute the first two iterations of the Power Method with scaling, starting with the given , rounding any numerical values to two decimal places.

Compute the first two iterations of the Power Method with scaling, starting with the given , rounding any numerical values to two decimal places.

Compute the first two iterations of the Inverse Power Method, starting with the given , rounding any numerical values to two decimal places.

Compute the first two iterations of the Shifted Inverse Power Method, starting with the given , to determine the eigenvalue of A closest to , rounding any numerical values to two decimal places.

The dominant eigenvalue of the matrix A given below is
. Compute the first two iterations of the Shifted Power Method with scaling, starting with the given , to determine the eigenvalue farthest from , rounding any numerical values to two decimal places.

Use the Power Method with scaling to determine an eigenvalue and associated eigenvector of A, starting with the given
.

Use the Power Method with scaling to determine an eigenvalue and associated eigenvector of A, starting with the given
.

Use the Power Method with scaling to determine an eigenvalue and associated eigenvector of A, starting with the given
.

The Power Method applied to the matrix and vector converges.

The Power Method applied to the matrix and vector converges.

The Inverse Power Method applied to the matrix and vector converges.

The Shifted Inverse Power Method for an invertible n×nmatrix Ais implemented by applying the Power Method to for some scalar c.

Suppose is a matrix having eigenvalues
. Then has dominant eigenvalue
.