Characteristic polynomial: Difference between revisions

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In linear algebra the characteristic polynomial of a square matrix is a polynomial which has the eigenvalues of the matrix as roots.

Let A be an n×n matrix. The characteristic polynomial of A is the determinant

\chi _{A}(X)=\det(A-XI_{n}),\,

where X is an indeterminate and I_n is an identity matrix.

The characteristic polynomial is unchanged under similarity, and hence be defined for an endomorphism of a vector space, independent of choice of basis.

The characteristic polynomial is monic of degree n;
The set of roots of the characteristic polynomial is equal to the set of eigenvalues of A.

The Cayley-Hamilton theorem states that a matrix satisfies its own characteristic polynomial.

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+{{subpages}}
 In [[linear algebra]] the '''characteristic polynomial''' of a [[square matrix]] is a polynomial which has the [[eigenvalue]]s of the matrix as roots.
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 where ''X'' is an indeterminate and ''I''<sub>''n''</sub> is an [[identity matrix]].
-The chcracteristic polynomial is unchanged under [[similarity]], and hence be defined for an [[endomorphism]] of a [[vector space]], independent of choice of [[basis (linear algebra)|basis]].
+The characteristic polynomial is unchanged under [[similarity]], and hence be defined for an [[endomorphism]] of a [[vector space]], independent of choice of [[basis (linear algebra)|basis]].
 ==Properties==
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 ==Cayley-Hamilton theorem==
-The '''Cayley-Hamilton theorem''' states that ''a matrix satisfies its own characteristic polynomial''.
+The '''Cayley-Hamilton theorem''' states that ''a matrix satisfies its own characteristic polynomial''.[[Category:Suggestion Bot Tag]]