Find the eigenvectors of the matrix.

Determine the eigenvalues of the matrix.

Apply the Laplace transform.

Solve the system using the determinant method.

Only the identity matrix.

The inverse of the matrix P.

A combination of eigenvectors and exponential functions of eigenvalues.

A single eigenvalue and its corresponding eigenvector.

To determine the eigenvalues of the matrix.

To calculate the trace of the matrix.

To find the inverse of the matrix.

To solve for the eigenvectors directly.

Gaussian elimination.

Matrix inversion.

Laplace transform.

Augmented matrix method.

[0, 0, 1]

[1, -1, 0]

[0, 1, -1]

[1, 0, 0]

[0, 0, 1]

[1, 0, -1]

[1, 1, 0]

[0, 1, -1]

As a polynomial function of time.

As a sum of eigenvectors multiplied by exponential functions of eigenvalues.

As a product of eigenvectors and eigenvalues.

As a single matrix equation.

It represents the solution as a matrix function of time.

It simplifies the eigenvalue calculation.

It eliminates the need for eigenvectors.

It provides a single solution to the system.

[1, 1, 0]

[0, 1, 1]

[0, 0, 0]

[1, 0, 1]

A matrix equation involving eigenvectors and exponential functions.

A polynomial equation.

A determinant equation.

A single vector solution.