What does the Eigenvalue of a linear system actually tell you?

In summary, eigenvalues of a linear system are scalar values that provide information about the system's behavior and geometry. They can be found in various ways and play a crucial role in describing the system's dynamics. They are also related to important concepts such as effective mass and diagonalizability of matrices.
  • #1
newclearwintr
3
0
I know that the eigenvalue of a linear system is a scalar such that Ax=λx. I know many ways to find the eigenvalue of a linear system. But I'm pulling my hair out trying to figure out what it is actually telling me about the system.

Can anyone give me a non-technical straight up answer on why eigenvalues are important and what that information provides us in regards to a linear system?

Thanks!
 
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  • #2
well if you had n independent eigenvectors all with eigenvalue 1, then A = Id.

If you have an orthogonal matrix in dim n= 2, and one eigenvalue is 1 and one eigenvalue is -1, you have a reflection.

... it helps describe the geometry of the map.
 
  • #3
welcome to pf!

hi newclearwintr! welcome to pf! :smile:

if A is a force or torque, then the eigenvalue is the effective mass or effective moment of inertia in a particular mode

if A is a derivative, then the eigenvalue is the time constant in a particular mode

(the only modes that will work are the eigenvectors …

if the system starts in any other mode, it won't stay in it, so the concept of effective mass or whatever is inapplicable)
 
  • #4


tiny-tim said:
hi newclearwintr! welcome to pf! :smile:

if A is a force or torque, then the eigenvalue is the effective mass or effective moment of inertia in a particular mode

if A is a derivative, then the eigenvalue is the time constant in a particular mode

(the only modes that will work are the eigenvectors …

if the system starts in any other mode, it won't stay in it, so the concept of effective mass or whatever is inapplicable)

Thanks for your response tiny-tim! So when you say it won't stay in the mode, we are saying that the mathematical model used to describe whatever phenomenon we're talking about will no longer be applicable? That constant is what allows the system to work (ie stay in the mode)?
 
  • #5
hi newclearwintr! :smile:

no, the mathematical model is fine …

suppose the equation is L = Iω (angular momentum = moment of inertia times angular velocity)

the I here is a tensor, not a number, and L is generally not parallel to ω

only if ω is parallel to a principal axis of the body, is L parallel to ω

ie the only modes with L parallel to ω are rotations about the principal axes (the eigenvectors)

for any other mode, even if angular momentum is constant (conserved), the angular velocity won't be … the rotation won't stay in the mode it started in!
 
  • #6
The trace of matrix A which equals the sum of its diagonal elements equals the sum of all eigenvalues of the matrix and the determinant of A equals the product of the eigenvalues. A is invertible if and only if all the eigenvalues are nonzero. The solutions of the characteristic polynomial of A are exactly its eigenvalues while a real matrix B is diagonalizable if all its eigenvalues are real and distinct. A symmetric matrix can be diagonalized in case its eigenvalues are distinct, eigenvalues of Hermitian matrices are real, and eigenvalues of skew-symmetric matrices are purely imaginary or zero. When A is invertible the eigenvalues of A^-1 are precisely the multiplicative inverses of the eigenvalues of A.

Planetmath: eigenvalues (of a matrix)
Wolfram Mathworld: Eigenvalue
Wikipedia: Eigenvalues
 
  • #7
I guess one way to think about eigenvectors is that they are vectors that the matrix only stretches or contracts. If the eigenvalue associated to an eigenvector is less than one, the matrix contracts the vector (makes it shorter) and if the eigenvalue is bigger than 1, the matrix stretches the vector. Of course, if the eigenvalue is 1, the matrix is just the identity on that vector.
 

1. What is an eigenvalue?

An eigenvalue is a scalar value that represents the amount by which a linear transformation, represented by a square matrix, changes the direction of an eigenvector.

2. How does the eigenvalue of a linear system relate to its eigenvectors?

The eigenvalues of a linear system determine the scaling factor of its corresponding eigenvectors. In other words, a linear transformation represented by a matrix multiplies an eigenvector by its eigenvalue.

3. What does a positive eigenvalue indicate about a linear system?

A positive eigenvalue indicates that the linear transformation stretches an eigenvector in the direction of its corresponding eigenvector.

4. What does a negative eigenvalue indicate about a linear system?

A negative eigenvalue indicates that the linear transformation shrinks an eigenvector in the direction of its corresponding eigenvector.

5. How does the magnitude of an eigenvalue affect the linear system?

The magnitude of an eigenvalue indicates the strength of the linear transformation in the direction of its corresponding eigenvector. A larger magnitude means a stronger transformation, while a smaller magnitude means a weaker transformation.

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