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DEFINITION 4.1
Let
be a square matrix over a field
.
A
Jordan-Chevalley decomposition
(also called SN-decomposition) of
is a decomposition of
which satisfies the following conditions.
-
is semisimple
(that means, the minimal polynomial of
has only simple roots.)
-
is nilpotent.
-
-
A main objective of this section is to prove the following proposition.
PROPOSITION 4.2
For any square matrix
over a field
, there exists a unique
Jordan-Chevalley decomposition.
To prove it, we need some basic facts from linear algebra.
PROOF..
Since
is an Euclidean domain, it is a principal ideal domain.
thus we see that there exists a polynomial
such that
holds. We put
Then we see easily that
are mutually orthogonal projection. That means, we have
It is also easy to see that both
and
commute with
.
Now putting
and
we see that
with
and
satisfying the required property.
COROLLARY 4.4
Every square matrix
over a field
is similar to a direct sum of
square matrices
with each
minimal polynomial
equals
to a power
of a irreducible polynomial
over
.
COROLLARY 4.5
When
is algebraically closed,
every square matrix
over a field
is similar to a direct sum of
square matrices
with each
minimal polynomial
equals
to a power
of a polynomial of degree
over
.
COROLLARY 4.6
A square matrix over a field
is semisimple if and only if it is
diagonalizable (similar to a diagonal matrix) over
.
COROLLARY 4.7
Let
be semisimple square matrices of the same size over
.
if
and
commute, then both
and
are also
semisimple.
PROOF..
Using commutativity of
and
, we may easily see that
and
are simultaneously diagonalizable over
.
COROLLARY 4.8
Let
be a field. Let
be a commutative subalgebra of
.
If
is generated by semisimple elements, then every element of
is also
semisimple.
On the other hand we have
LEMMA 4.9
Let
be a field. Let
be a commutative subalgebra of
.
If
is generated by nilpotent elements, then every element of
is also
nilpotent.
PROOF..
Easy.
COROLLARY 4.10
A Jordan-Chevalley decomposition (if there exists)
of a square matrix
is unique.
PROOF..
Let
be two Jordan-Chevalley decompositions. Then
is a semisimple nilpotent element.
Thus
.
PROOF..
(of Proposition
4.2.)
It now remains to prove that Jordan-Chevalley decomposition of a square matrix
exists. By definition we may assume that
is algebraically closed.
In view of Corollary
4.5, we may then assume that
the minimal polynomial
of
is of the form
for some
and
. Then
gives the required Jordan-Chevalley decomposition.
DEFINITION 4.11
Let
be a field.
For any square matrix
, we denote by
(respectively,
)
the semisimple (respectively, nilpotent) part of
in the Jordan-Chevalley
decomposition of
.
LEMMA 4.12
Let
be a field.
Let
be a square matrix.
then we have
PROOF..
Follows easily from the uniqueness of the Jordan-Chevalley decomposition.
ARRAY(0x8eef838)ARRAY(0x8eef838)ARRAY(0x8eef838)ARRAY(0x8eef838)
Next: -rationality
Up: Jordan-Chevalley decomposition of a
Previous: Jordan-Chevalley decomposition of a
2009-03-06