Similar Matrices
We say that two $n \times n$ matrices $A$ and $B$ are similar
- if for some invertible $M$ we can write $B = M^{-1} A \, M$
Invariant Subspaces
Invariant subspace
- we know that if $x$ is the eigenvector of $A$, then $Ax = \lambda x$
- $A$ only "streches" $x$ - but it remains in the same 1-dimensional subspace
- so such subspace $S$ formed by $x$ is invariant:
- if $x \in S \Rightarrow Ax \in S$
Invariant column space
- If there exists such $M$ that $AM = MB$
- then the $\text{range}(A)$ (the Column Space of $A$) is invariant
Families
Suppose $A$ has all its eigenvalues
- then if we diagonalize $A$, we have $S^{-1} A \, S = \Lambda$
- so $A$ is similar to $\Lambda$
- Here $M = \Lambda$
- we may take another $M \ne \Lambda$ and will get another matrix similar to $A$ (not necessarily diagonal)
A family of similar matrices for $A$ is a set of all matrices similar for $A$ (for different $M$s)
Why Similar?
What is similar about such $A$ and $B$?
- they have the same eigenvalues!
Let's check it:
- let $A \mathbf x = \lambda \mathbf x$
- and $B = M^{-1} A \, M$
- then $A \mathbf x = A I \mathbf x = A M M^{-1} \mathbf x = \lambda \mathbf x$
- now let's multiply by $M^{-1}$ on the left:
- $\underbrace{M^{-1} A \, M}_{B} \, M^{-1} \mathbf x = M^{-1} \lambda \mathbf x$
- $B M^{-1} \mathbf x = M^{-1} \lambda \mathbf x$
- Let $\mathbf x^*$ be $M^{-1} \mathbf x$, so we have
- $B \mathbf x^* = \lambda \mathbf x^*$
- so matrices $A$ and $B$ share the same eigenvalue $\lambda$
- but not the eigenvector! $\mathbf x \ne \mathbf x^*$
Diagonalization
For diagonalization
- $A = S^{-1} \Lambda \, S$ eigenvalues stay the same, but eigenvectors become unit vectors
What if for some $i \ne j$, $\lambda_i = \lambda_j$?
- there might be not enough eigenvectors to span $\mathbb R^n$
- i.e. columns of $A$ are not linearly independent
Other Things
There are other things that make these matrices similar.
$M$ does not change:
- eigenvalues $\lambda_i$ (as discussed earlier)
- Trace and Determinant (because $\text{tr}(A) = \sum \lambda_i$ and $\text{det}(A) = \prod \lambda_i$)
- rank, and therefore number of independent eigenvectors
$M$ does change
Jordan Form
Suppose $A$ has a family of similar matrices
- then the Jordan Form is the most diagonal matrix of the family
Sources