Eigenvalue and Eigenvector Calculator

eigenvalue and eigenvector calculator

Enter Matrix Values:

Results:

Enter values and click Calculate to see eigenvalues and eigenvectors.

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Calculator Use

The eigenvalue and eigenvector calculator is a specialized tool designed to solve the characteristic equation of a 2×2 square matrix. This tool is essential for students and engineers working with linear transformations, structural analysis, and vibration modeling. By entering the four components of a matrix, you can instantly find the scalars (eigenvalues) and the associated directions (eigenvectors) that remain unchanged in direction during a linear transformation.

a11, a12, a21, a22

These represent the elements of the square matrix A. In a standard 2×2 grid, a11 is top-left, a12 is top-right, a21 is bottom-left, and a22 is bottom-right.

Show Steps

Check this box to view the derived characteristic quadratic equation before the final results.

How It Works

To find the eigenvalues, the calculator solves the equation det(A – λI) = 0, where I is the identity matrix and λ represents the eigenvalues. For a 2×2 matrix, this results in a quadratic equation known as the characteristic equation:

λ² – tr(A)λ + det(A) = 0

• tr(A) (Trace): The sum of the diagonal elements (a11 + a22).
• det(A) (Determinant): The value (a11 * a22) – (a12 * a21).
• Eigenvectors: Once λ is found, the calculator solves (A – λI)v = 0 to find the non-zero vector v.

Calculation Example

Example: Find the eigenvalues and eigenvectors for the matrix A = [[4, 1], [2, 3]].

Step-by-step solution:

1. Identify Values: a11=4, a12=1, a21=2, a22=3.
2. Calculate Trace: 4 + 3 = 7.
3. Calculate Determinant: (4 * 3) – (1 * 2) = 12 – 2 = 10.
4. Characteristic Equation: λ² – 7λ + 10 = 0.
5. Solve for λ: (λ – 5)(λ – 2) = 0. So, λ₁ = 5, λ₂ = 2.
6. Result: The eigenvalues are 5 and 2. The calculator then computes the normalized eigenvectors based on these values.

Common Questions

What is an eigenvalue?

An eigenvalue is a scalar that indicates how much a corresponding eigenvector is stretched or compressed during a linear transformation. If the eigenvalue is negative, the direction of the vector is reversed.

Why are eigenvectors normalized?

Eigenvectors represent a direction. Since any scalar multiple of an eigenvector is also an eigenvector, this calculator provides a "normalized" version (a unit vector with a length of 1) for consistency and ease of use in further physics or engineering calculations.

Can a matrix have complex eigenvalues?

Yes. If the discriminant of the characteristic equation is negative, the eigenvalues will be complex numbers. This usually indicates a rotation in the transformation rather than just a simple scaling.