Prove that A is invertible if $A^2 - 4A -7I = 0$. [duplicate]

The $2 \times 2$ matrix $A$ satisfies

$$A^2 - 4A -7I = 0,$$

where $I$ is the identity matrix. Prove that $A$ is invertible.

I'm not sure how to do this. Help would be appreciated.

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• Hint: $A(A-4I) = 7I$. – Anurag A May 24 '15 at 22:28
• Not in characteristic $7$, though. – Pedro Tamaroff May 24 '15 at 22:28

Observe that $$\left(\frac17(A-4I)\right)A=I$$
Hint: write $I = AA^{-1}$, so that: $$A^2-4A - 7AA^{-1} = 0.$$Can you solve for $A^{-1}$?
• It's similar to real numbers, you only have to remember that not always matrices commute, and not always you can "divide" (i.e., multiply everything by the inverse). Here we would have: $$7AA^{-1} = A(A-4I) \implies AA^{-1} = \frac{1}{7}A(A-4I).$$ Since we assume that $A^{-1}$ exists, you can multiply both sides by $A^{-1}$ by the left, so we get only $A^{-1}$ on the left side. I'll let you finish it now. – Ivo Terek May 24 '15 at 22:34
you can rewrite $A^2 - 4A - 7I = 0$ as $$A\left(\frac17A-\frac47I\right) = I.$$ therefore $A$ is invertible and $$A^{-1} = \frac17A-\frac47I.$$
• @ZachEffman, i agree. anyone who bothers with characteristic $7$ and the like is unlikely ask this question in the first place. – abel May 24 '15 at 22:38