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Let $a$ and $b$ be distinct nonzero real numbers and let $A\in \mathbb{R}^{n\times n}(n\geq 2)$ with each diagonal entry equal to $a$ and each off-diagonal entry equal to $b$.

  1. Determine all eigenvalues and eigenvectors of $A$ together with their algebraic multiplicities.
  2. Is $A$ diagonalizable? Why?
  3. Determine the minimal polynomial of $A$.

My idea: Considering a $4\times 4$ matrix for simplicity:

$\left( \begin{array}{ccccc} a& b&b & b \\ b &a&b &b \\ b & b&a& b\\ b&b&b&a \end{array} \right)$ now we perform row operations to transform this matrix into a simple one like this: $\left( \begin{array}{ccccc} a-b& b-a& 0 & 0 \\ 0 &a-b& b-a&0 \\ 0 & 0&a-b & b-a\\ b&b&b&a \end{array} \right)$ Then find the eigen values and from there eigen vectors? I think eigen values are $a\pm b$ but not sure how to prove it.

Thanks Marvis, your answer is very helpful.

Can you also comment on my ideas about the rest of the problem: to find eigen vectors we need $x$ such that $(A-\lambda I)x=0.$ So, $\lambda =a-b$ gives me that $(A-\lambda I)=(b)$ a matrix with all entries $b$, thus eigen vector in this case is a $n\times 1$ vector with first entry $n-1$ and the rest of the entries as 1's. So, using the eigen vectors I can find an invertible matrix $P$ and find out if $P^{-1}AP=D$ where $D$ is a diagonal matrix? Then I can get minimal polynomial from the diagonal matrix.

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    If every row of a matrix has the same sum, then the sum is an eigenvalue with eigenvector $(1,1,1,1)^T$. Here, you have an eigenvalue $a+3b$ with corresponding eigenvector $(1,1,1,1)^T$.2012-07-08

2 Answers 2

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HINT 1: Your matrix $A$ is $(a-b)I + b e e^T$

Can you now compute the eigenvalues?

Move your mouse over the gray area below for another hint.

HINT 2: Make use of the fact that $\text{eigen}(\lambda A) = \lambda \text{eigen}(A)$

Move your mouse over the gray area below for another hint.

HINT 3: $\text{eigen}(I + \alpha e e^T)$ are $1 + n\alpha$ and $1$($n-1$ times).

Move your mouse over the gray area for the complete answer.

$\text{eigen} ((a-b)I + b e e^T) = (a-b) \text{eigen} \left( I + \dfrac{b}{a-b} e e^T\right)$ Hence, all we need is to find the eigenvalues of $I + \alpha ee^T$, where $\alpha = \dfrac{b}{a-b}$ in our case. Note that $ee^T$ is a rank one matrix and its eigen values are $e^Te = n$ and $n-1$ zeros. If $\lambda$ is an eigen value of $I + \alpha ee^T$, then $\det (I + \alpha ee^T - \lambda I) = \alpha^n \det \left(ee^T + \dfrac{(1-\lambda)}{\alpha}I \right) = 0$ This means that $-\dfrac{(1-\lambda)}{\alpha}$ are the eigenvalues of $ee^T$. Hence, we get that $-\dfrac{(1-\lambda)}{\alpha} = n \text{ or }0 \text{ ($n-1$ times)}.$ Hence, we get that $\lambda = 1 + n \alpha, 1 \text{ ($n-1$ times)}$ Hence, the eigenvalues of the initial matrix are $\lambda = (a-b) + nb, (a-b) \text{ ($n-1$ times)}$ The determinant of this matrix is $((a-b)+nb)(a-b)^{n-1} = (a-b)^n + nb(a-b)^{n-1}$

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    Thanks Marvis, your answer is very helpful.2012-07-08
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To take up the last part of the problem: if $\lambda=a-b$ then $A-\lambda I$ is a matrix of rank one, hence, of nullity $n-1$, so the eigenspace for the eigenvalue $\lambda$ has dimension $n-1$. That means that to diagonalize $A$ it's not enough to find one eigenvector; you must find $n-1$ linearly independent eigenvectors; $n-1$ linearly independent vectors in the nullspace of the all-$b$ matrix. Can you do that?