Section5.3Eigenvalues and Characteristic Polynomials (GT3)
Learning Outcomes
Find the eigenvalues of a \(2\times 2\) matrix.
Subsection5.3.1Warm Up
Activity5.3.1.
Let \(R\colon\IR^2\to\IR^2\) be the transformation given by rotating vectors about the origin through and angle of \(45^\circ\text{,}\) and let \(S\colon\IR^2\to\IR^2\) denote the transformation that reflects vectors about the line \(x_1=x_2\text{.}\)
(a)
If \(L\) is a line, let \(R(L)\) denote the line obtained by applying \(R\) to it. Are there any lines \(L\) for which \(R(L)\) is parallel to \(L\text{?}\)
(b)
Now consider the transformation \(S\text{.}\) Are there any lines \(L\) for which \(S(L)\) is parallel to \(L\text{?}\)
Subsection5.3.2Class Activities
Activity5.3.2.
An invertible matrix \(M\) and its inverse \(M^{-1}\) are given below:
Furthermore, a square matrix \(M\) is invertible if and only if \(\det(M)\not=0\text{.}\)
Observation5.3.4.
Consider the linear transformation \(A : \IR^2 \rightarrow \IR^2\) given by the matrix \(A = \left[\begin{array}{cc} 2 & 2 \\ 0 & 3 \end{array}\right]\text{.}\)
Let \(A \in M_{n,n}\text{.}\) An eigenvector for \(A\) is a vector \(\vec{x} \in \IR^n\) such that \(A\vec{x}\) is parallel to \(\vec{x}\text{.}\)
In other words, \(A\vec{x}=\lambda \vec{x}\) for some scalar \(\lambda\text{.}\) If \(\vec x\not=\vec 0\text{,}\) then we say \(\vec x\) is a nontrivial eigenvector and we call this \(\lambda\) an eigenvalue of \(A\text{.}\)
Activity5.3.6.
Finding the eigenvalues \(\lambda\) that satisfy
\begin{equation*}
A\vec x=\lambda\vec x=\lambda(I\vec x)=(\lambda I)\vec x
\end{equation*}
for some nontrivial eigenvector \(\vec x\) is equivalent to finding nonzero solutions for the matrix equation
\begin{equation*}
(A-\lambda I)\vec x =\vec 0\text{.}
\end{equation*}
(a)
If \(\lambda\) is an eigenvalue, and \(T\) is the transformation with standard matrix \(A-\lambda I\text{,}\) which of these must contain a non-zero vector?
The kernel of \(T\)
The image of \(T\)
The domain of \(T\)
The codomain of \(T\)
(b)
Therefore, what can we conclude?
\(A\) is invertible
\(A\) is not invertible
\(A-\lambda I\) is invertible
\(A-\lambda I\) is not invertible
(c)
And what else?
\(\displaystyle \det A=0\)
\(\displaystyle \det A=1\)
\(\displaystyle \det(A-\lambda I)=0\)
\(\displaystyle \det(A-\lambda I)=1\)
Fact5.3.7.
The eigenvalues \(\lambda\) for a matrix \(A\) are exactly the values that make \(A-\lambda I\) non-invertible.
Thus the eigenvalues \(\lambda\) for a matrix \(A\) are the solutions to the equation
Compute \(\det (A-\lambda I)\) to determine the characteristic polynomial of \(A\text{.}\)
(b)
Set this characteristic polynomial equal to zero and factor to determine the eigenvalues of \(A\text{.}\)
Activity5.3.10.
Find all the eigenvalues for the matrix \(A=\left[\begin{array}{cc} 3 & -3 \\ 2 & -4 \end{array}\right]\text{.}\)
Activity5.3.11.
Find all the eigenvalues for the matrix \(A=\left[\begin{array}{cc} 1 & -4 \\ 0 & 5 \end{array}\right]\text{.}\)
Activity5.3.12.
Find all the eigenvalues for the matrix \(A=\left[\begin{array}{ccc} 3 & -3 & 1 \\ 0 & -4 & 2 \\ 0 & 0 & 7 \end{array}\right]\text{.}\)
Subsection5.3.3Individual Practice
Activity5.3.13.
Let \(A\in M_{n,n}\) and \(\lambda\in\IR\text{.}\) The eigenvalues of \(A\) that correspond to \(\lambda\) are the vectors that get stretched by a factor of \(\lambda\text{.}\) Consider the following special cases for which we can make more geometric meaning.
(a)
What are some other ways we can think of the eigenvectors corresponding to eigenvalue \(\lambda=0\text{?}\)
(b)
What are some other ways we can think of the eigenvectors corresponding to eigenvalue \(\lambda=1\text{?}\)
(c)
What are some other ways we can think of the eigenvectors corresponding to eigenvalue \(\lambda=-1\text{?}\)
(d)
How might we interpret a matrix that has no (real) eigenvectors/values?
What are the maximum and minimum number of eigenvalues associated with an \(n \times n\) matrix? Write small examples to convince yourself you are correct, and then prove this in generality.