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Eigenvalues and eigenvectors/2/Introduction/Section

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For a reflection at an axis in the plane, certain vectors behave particularly simply. The vectors on the axis are sent to themselves, and the vectors which are orthogonal to the axis are sent to their negatives. For all these vectors, the image under this linear mapping lies on the line spanned by these vectors. In the theory of eigenvalues and eigenvectors, we want to know whether, for a given linear mapping, there exist lines (one-dimensional linear subspaces), which are mapped to themselves. The goal is to find, for the linear mapping, a basis such that the describing matrix is quite simple. Here, an important application is to find solutions for a system of linear differential equations.

A reflection at an axis has two eigenlines, the axis with eigenvalue and the orthogonal line with eigenvalue .


Let be a field, a -vector space and

a linear mapping. Then an element , , is called an eigenvector of (for the eigenvalue ), if

for some

holds.

To paraphrase, an eigenvector is a vector which is linearly dependent to .

A shear mapping has one eigenline for the eigenvalue , and no further eigenvalues.


Let be a field, a -vector space and

a linear mapping. Then an element is called an eigenvalue for , if there exists a vector , such that

The set of all eigenvalues is called the spectrum of .


Let be a field, a -vector space and

a linear mapping. For , we denote by

the eigenspace of for the value .


Thus we allow arbitrary values (not only eigenvalues) in the definition of an eigenspace. We will see in fact that they are linear subspaces. In particular, belongs to every eigenspace, though it is never an eigenvector. The linear subspace generated by an eigenvector is called an eigenline. For most (in fact all up to finitely many, in case the vector space has finite dimension) , the eigenspace is just the zero space.


In case of a homothety with factor , every vector is an eigenvector for the eigenvalue . The eigenspace of the eigenvalue is the total space. Also, we can restrict an endomorphism to any eigenspace (as source and target), yielding the mapping

This mapping is just the homothety with factor .

For matrices, we use the same concepts. If is a linear mapping, and is a describing matrix with respect to a basis, then for an eigenvalue and an eigenvector with corresponding coordinate tuple with respect to the basis, we have the relation


We consider the linear mapping

given by the diagonal matrix

The diagonal entries are the eigenvalues of , and the -th standard vector is a corresponding eigenvector. The eigenspaces are

These spaces are not if and only if equals one of the diagonal entries. The dimension of the eigenspace is given by the number how often the value occurs in the diagonal. The sum of all these dimension gives .


We consider the linear mapping

given by the matrix

The question whether this mapping has eigenvalues, leads to the question whether there exists some , such that the equation

has a nontrivial solution . For a given , this is a linear problem and can be solved with the elimination algorithm. However, the question whether there exist eigenvalues at all, leads, due to the variable "eigenvalue parameter“ , to a nonlinear problem. The system of equations above is

For , we get , but the null vector is not an eigenvector. Hence, suppose that . Both equations combined yield the condition

hence . But in , the number does not have a square root, therefore there is no solution, and that means that has no eigenvalues and no eigenvectors.

Now we consider the matrix as a real matrix, and look at the corresponding mapping

The same computations as above lead to the condition , and within the real numbers, we have the two solutions

For both values, we have now to find the eigenvectors. First, we consider the case , which yields the linear system

We write this as

and as

This system can be solved easily, the solution space has dimension one, and

is a basic solution.

For , we do the same steps, and the vector

is a basic solution. Thus over , the numbers and are eigenvalues, and the corresponding eigenspaces are


Let be a field, a -vector space and

a

linear mapping. Then the following statements hold.
  1. Every eigenspace

    is a linear subspace of .

  2. is an eigenvalue for , if and only if the eigenspace is not the null space.
  3. A vector , is an eigenvector for , if and only if .

(1). Let and let . Then

(2) and (3) follow directly from the definitions.