Finding eigenvalues of an unknown matrix subtracted by the identity matrix

$x$ is an eigenvalue if $det(A - xI) = 0$. Rewrite slightly to get $$ det((A-I) - (x-1)I) = 0 $$ or $$ det((A-I) - yI) = 0. $$

So: a solution $y$ to the last equation is an eigenvalue of $A-I$. But in that case, $x = y+1$ is an eigenvalue of $A$. So your conjecture is correct.


For any matrix $B$, we have that $\lambda$ is an eigenvalue of $B$ with eigenvector $v$ if and only if, for all scalars $\mu$, $\lambda + \mu$ is an eigenvalue of $B + \mu I$ with the same eigenvector, since

$Bv = \lambda v \tag{1}$

is clearly equivalent to

$(B + \mu I)v = Bv + \mu I v = (\lambda + \mu)v. \tag{2}$

Applying this equivalence to the case at hand shows that the eigenvalues of $A$ are indeed $-1$, $0$, and $2$.

Hope this helps. Cheerio,

and as always,

Fiat Lux!!!

Tags:

Linear Algebra

Eigenvalues Eigenvectors

Related

How prove this two symmetric matrices $AB=0$ In statistics, why do you reject the null hypothesis when the p-value is less than the alpha value (the level of significance) Confused about the definition of a group as a groupoid with one object. Calculating $\int_{0}^{\infty} x^{a-1} \cos(x) \ \mathrm dx = \Gamma(a) \cos (\pi a/2)$ Prove $(a + b) \bmod n = (a \bmod n + b \bmod n) \bmod n$ Group with exactly two subgroups of index 2 Is an integer a sum of two rational squares iff it is a sum of two integer squares? Let $a, b, c$ be positive real numbers such that $abc = 1$. Prove that $a^2 + b^2 + c^2 \ge a + b + c$. Solve $3^x + 28^x=8^x+27^x$ Homogeneous riemannian manifolds are complete. Trouble understanding proof. Calculating the shortest distance between n number of points on a scatter graph Is statistical dependence transitive?

Recent Posts