Semi-simple endomorphism

semi-simple linear transformation, of a vector space $V$ over a field $K$

An endomorphism $\alpha$ of $V$ with the following property: For any $\alpha$-invariant subspace $W$ of $V$ there exists an $\alpha$-invariant subspace $W'$ such that $V$ is the direct sum of $W$ and $W'$. In other words, $V$ should be a semi-simple module over the ring $K[X]$ with $X$ acting as $\alpha$. For example, any orthogonal, symmetric or skew-symmetric linear transformation of a finite-dimensional Euclidean space, and also any diagonalizable (i.e. representable by a diagonal matrix with respect to some basis) linear transformation of a finite-dimensional vector space, is a semi-simple endomorphism. The semi-simplicity of an endomorphism is preserved by passage to an invariant subspace $W \subset V$, and to the quotient space $V/W$.

Let $\dim V < \infty$. An endomorphism $\alpha$ is semi-simple if and only if its minimum polynomial (cf. Matrix) has no multiple factors. Let $L$ be an extension of the field $K$ and let $\alpha_L$ be the extension of the endomorphism $\alpha \otimes 1$ to the space $V_L = V \otimes K$. If $\alpha_L$ is semi-simple, then $\alpha$ is also semi-simple, and if $L$ is separable over $K$, then the converse is true. An endomorphism $\alpha$ is called absolutely semi-simple if $\alpha_L$ is semi-simple for any extension $L/K$; for this it is necessary and sufficient that the minimum polynomial has no multiple roots in the algebraic closure $\bar K$ of $K$, that is, that the endomorphism $\alpha$ is diagonalizable.

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Comments

Over an algebraically closed field any endomorphism $\alpha$ of a finite-dimensional vector space can be decomposed into a sum $\alpha = s + n$ of a semi-simple endomorphism $\sigma$ and a nilpotent one $\nu$ such that $\sigma \nu = \nu \sigma$; cf. Jordan decomposition, 2).