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Minimal polynomial

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The minimal polynomial of an n-by-n matrix A over a field F is the polynomial p(x) with leading coefficient 1 over F of least degree such that p(A)=0. Any other polynomial q with q(A) = 0 is a (polynomial) multiple of p.

The following three statements are equivalent:

  1. λ∈F is a root of p(x),
  2. λ is a root of the characteristic polynomial of A,
  3. λ is an eigenvalue of A.

The multiplicity of a root λ of p(x) is the geometric multiplicity of λ and is the size of the largest Jordan block corresponding to λ and the dimension of the corresponding eigenspace.

The minimal polynomial is not always the same as the characteristic polynomial. Consider the matrix 4 I n {\displaystyle 4I_{n}} , which has characteristic polynomial ( x 4 ) n {\displaystyle (x-4)^{n}} . However, the minimal polynomial is x 4 {\displaystyle x-4} , since 4 I 4 I = 0 {\displaystyle 4I-4I=0} as desired, so they are different for n 2 {\displaystyle n\geq 2} . That the minimal polynomial always divides the characteristic polynomial is a consequence of the Cayley–Hamilton theorem.


In field theory, given a field extension E/F and an element α of E which is algebraic over F, the minimal polynomial of α is the monic polynomial p, with coefficients in F, of least degree such that p(α) = 0. The minimal polynomial is irreducible, and any other non-zero polynomial f with f(α) = 0 is a multiple of p.

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