Main room

The main space is a term from linear algebra and a generalization of the eigenspace . Main rooms play a major role in setting up the Jordanian normal form and calculating an associated basis.

Definition of the main room

If a linear mapping from a finite-dimensional vector space in itself is an eigenvalue of and denotes the algebraic multiplicity of the eigenvalue , then one calls the kernel of the -fold execution of main space to the eigenvalue , i.e. H. ${\ displaystyle F \ colon V \ to V}$ ${\ displaystyle V}$ ${\ displaystyle \ lambda}$ ${\ displaystyle F}$ ${\ displaystyle r}$ ${\ displaystyle \ lambda}$ ${\ displaystyle r}$ ${\ displaystyle (F- \ lambda \, \ mathrm {id})}$ ${\ displaystyle \ lambda}$

{\ displaystyle \ operatorname {Hau} (F, \ lambda): = \ {v \ in V \ mid (F- \ lambda \, \ mathrm {id}) ^ {r} (v) = 0 {\ text { for a}} r \ in \ mathbb {N} \}}

.

Here is the identity mapping on . The main space is thus spanned by precisely those vectors for which applies. In particular, the eigenspace for an eigenvalue is a subspace of the main space for this eigenvalue. ${\ displaystyle \ mathrm {id}}$ ${\ displaystyle V}$ ${\ displaystyle v}$ ${\ displaystyle (F- \ lambda \, \ mathrm {id}) ^ {r} (v) = 0}$

Main vector

The elements of the main space are also sometimes called main vectors . A level or a level can be assigned to these main vectors. Let be an endomorphism and an eigenvalue of the endomorphism. A vector is called the main vector of the stage if ${\ displaystyle F}$ ${\ displaystyle \ lambda}$ ${\ displaystyle v}$ ${\ displaystyle p}$

{\ displaystyle (F- \ lambda \, \ mathrm {id}) ^ {p} (v) = 0}

but

{\ displaystyle (F- \ lambda \, \ mathrm {id}) ^ {p-1} (v) \ neq 0}

applies. All eigenvectors are thus main vectors of level 1.

Theorem about main space decomposition

Let it be an endomorphism and its characteristic polynomial ${\ displaystyle F}$

{\ displaystyle \ chi _ {F} (t) = \ pm \ prod _ {j = 1} ^ {k} (t- \ lambda _ {j}) ^ {r_ {j}}}

decay completely into linear factors with different pairs . Then: ${\ displaystyle \ lambda _ {1} \ ldots \ lambda _ {k} \ in K}$

The main room is -invariant, that is . ${\ displaystyle F}$ ${\ displaystyle F \ left (\ operatorname {Hau} (F, \ lambda _ {i}) \ right) \ subset \ operatorname {Hau} (F, \ lambda _ {i})}$
The dimensions of the main rooms are consistent with the multiplicities of the zeros of the characteristic polynomial match, so . ${\ displaystyle \ dim \ left (\ operatorname {Hau} (F, \ lambda _ {i}) \ right) = r_ {i}}$
The main spaces form a direct decomposition ( inner direct sum ) of . So it applies . ${\ displaystyle V}$ ${\ displaystyle V = \ operatorname {Hau} (F, \ lambda _ {1}) \ oplus \ cdots \ oplus \ operatorname {Hau} (F, \ lambda _ {k})}$
The endomorphism has a decomposition . In it is diagonalizable , is nilpotent , and it is true . ${\ displaystyle F}$ ${\ displaystyle F = F_ {D} + F_ {N}}$ ${\ displaystyle F_ {D}}$ ${\ displaystyle F_ {N}}$ ${\ displaystyle F_ {D} \ circ F_ {N} = F_ {N} \ circ F_ {D}}$

example

Given a matrix whose characteristic polynomial breaks down into linear factors: ${\ displaystyle A \ in \ mathbb {R} ^ {6 \ times 6}}$

{\ displaystyle \ det \ left (A- \ lambda I \ right) = (\ lambda -2) ^ {3} (\ lambda -4) ^ {3}}

.

In addition, the following should apply:

{\ displaystyle {\ begin {aligned} \ dim \ operatorname {Ker} \ left (A-2I \ right) & = 2 \ ,, \ quad \ dim \ operatorname {Ker} \ left (A-2I \ right) ^ {2} = 3 \ ,, \ quad \ dim \ operatorname {Ker} \ left (A-2I \ right) ^ {3} = 3 \\\ dim \ operatorname {Ker} \ left (A-4I \ right) & = 1 \ ,, \ quad \ dim \ operatorname {Ker} \ left (A-4I \ right) ^ {2} = 2 \ ,, \ quad \ dim \ operatorname {Ker} \ left (A-4I \ right ) ^ {3} = 3 \\\ end {aligned}}}

The algebraic multiplicity of the eigenvalue 2 is 3 and that of the eigenvalue 4 is 3. The eigenspaces have the dimension 2 or 1, ie smaller than the respective algebraic multiplicity, which is why the matrix cannot be diagonalized. But the Jordan normal form can be constructed ${\ displaystyle J}$

{\ displaystyle J = {\ begin {bmatrix} 2 & 0 & 0 & 0 & 0 & 0 \\ 0 & 2 & 1 & 0 & 0 & 0 \\ 0 & 0 & 2 & 0 & 0 & 0 \\ 0 & 0 & 0 & 4 & 1 & 0 \\ 0 & 0 & 0 & 0 & 4 & 1 \\ 0 & 0 & 0 & 0 & 0 & 4} \ end} {bmatrix

via a similarity transformation with the transformation matrix ${\ displaystyle P}$

{\ displaystyle P ^ {- 1} AP = J \ quad \ Longleftrightarrow \ quad AP = PJ}

,

where the column vectors of the main vectors correspond to: ${\ displaystyle P}$ ${\ displaystyle p_ {i}}$

{\ displaystyle P = {\ begin {bmatrix} p_ {1} & p_ {2} & p_ {3} & p_ {4} & p_ {5} & p_ {6} \ end {bmatrix}}}

The transformation reads with the help of the main vectors: ${\ displaystyle AP = PJ}$

{\ displaystyle A {\ begin {bmatrix} p_ {1} & p_ {2} & p_ {3} & p_ {4} & p_ {5} & p_ {6} \ end {bmatrix}} = {\ begin {bmatrix} p_ {1 } & p_ {2} & p_ {3} & p_ {4} & p_ {5} & p_ {6} \ end {bmatrix}} J = {\ begin {bmatrix} 2p_ {1} & 2p_ {2} & 2p_ {3} + p_ { 2} & 4p_ {4} & 4p_ {5} + p_ {4} & 4p_ {6} + p_ {5} \ end {bmatrix}}}

So it follows:

{\ displaystyle {\ begin {aligned} \ left (A-2I \ right) p_ {1} & = 0 \\\ left (A-2I \ right) p_ {2} & = 0 \\\ left (A- 2I \ right) p_ {3} & = p_ {2} \ quad \ Rightarrow \ quad \ left (A-2I \ right) ^ {2} p_ {3} = \ left (A-2I \ right) p_ {2 } = 0 \\\ left (A-4I \ right) p_ {4} & = 0 \\\ left (A-4I \ right) p_ {5} & = p_ {4} \ quad \ Rightarrow \ quad \ left (A-4I \ right) ^ {2} p_ {5} = \ left (A-4I \ right) p_ {4} = 0 \\\ left (A-4I \ right) p_ {6} & = p_ { 5} \ quad \ Rightarrow \ quad \ left (A-4I \ right) ^ {3} p_ {6} = \ left (A-4I \ right) ^ {2} p_ {5} = \ left (A-4I \ right) p_ {4} = 0 \ end {aligned}}}

${\ displaystyle p_ {1}}$ , and are main vectors of the first order (i.e. eigenvectors), and main vectors of the second order and is a main vector of the third order. ${\ displaystyle p_ {2}}$ ${\ displaystyle p_ {4}}$ ${\ displaystyle p_ {3}}$ ${\ displaystyle p_ {5}}$ ${\ displaystyle p_ {6}}$

The cores of the mappings are spanned by the main vectors as follows: ${\ displaystyle A- \ lambda E}$

{\ displaystyle {\ begin {aligned} \ operatorname {Ker} \ left (A-2I \ right) & = \ left \ langle p_ {1}, p_ {2} \ right \ rangle \ ,, \ quad \ operatorname { Ker} \ left (A-2I \ right) ^ {n} = \ left \ langle p_ {1}, p_ {2}, p_ {3} \ right \ rangle \ {\ text {with}} \ n \ geq 2 \ ,, \\\ operatorname {Ker} \ left (A-4I \ right) & = \ left \ langle p_ {4} \ right \ rangle \ ,, \ quad \ operatorname {Ker} \ left (A-4I \ right) ^ {2} = \ left \ langle p_ {4}, p_ {5} \ right \ rangle \ ,, \ quad \ operatorname {Ker} \ left (A-4I \ right) ^ {n} = \ left \ langle p_ {4}, p_ {5}, p_ {6} \ right \ rangle \ {\ text {with}} \ n \ geq 3 \ end {aligned}}}

The main spaces and eigenspaces for the two eigenvalues are thus, with the eigenspaces being subspaces of the respective main spaces:

{\ displaystyle {\ begin {aligned} \ operatorname {Hau} (A, 2) = \ operatorname {Ker} (A-2I) ^ {2} = \ left \ langle p_ {1}, p_ {2}, p_ {3} \ right \ rangle & \ supset \ operatorname {E} (A, 2) = \ operatorname {Ker} (A-2I) = \ left \ langle p_ {1}, p_ {2} \ right \ rangle \ \\ operatorname {Hau} (A, 4) = \ operatorname {Ker} (A-4I) ^ {3} = \ left \ langle p_ {4}, p_ {5}, p_ {6} \ right \ rangle & \ supset \ operatorname {E} (A, 4) = \ operatorname {Ker} (A-4I) = \ left \ langle p_ {4} \ right \ rangle \ end {aligned}}}

The dimensions of the main spaces agree with the multiples of the zeros of the characteristic polynomial, i.e. and . The main rooms form a direct decomposition of , i. H. . ${\ displaystyle \ dim \ left (\ operatorname {Hau} (A, 2) \ right) = 3}$ ${\ displaystyle \ dim \ left (\ operatorname {Hau} (A, 4) \ right) = 3}$ ${\ displaystyle V = \ mathbb {R} ^ {6}}$ ${\ displaystyle V = \ operatorname {Hau} (A, 2) \ oplus \ operatorname {Hau} (A, 4)}$

The matrix has a decomposition , whereby it is diagonalizable and nilpotent: with ${\ displaystyle A}$ ${\ displaystyle A = A_ {D} + A_ {N}}$ ${\ displaystyle A_ {D}}$ ${\ displaystyle A_ {N}}$ ${\ displaystyle P ^ {- 1} (A_ {D} + A_ {N}) P = J_ {D} + J_ {N}}$

{\ displaystyle J_ {D} = {\ begin {bmatrix} 2 & 0 & 0 & 0 & 0 & 0 \\ 0 & 2 & 0 & 0 & 0 & 0 \\ 0 & 0 & 2 & 0 & 0 & 0 \\ 0 & 0 & 0 & 4 & 0 & 0 \\ 0 & 0 & 0 & 0 & 4 & 0 \\ 0 & 0 & 0}} & 0, b \ matrix \ begin {{{{0} end \ N & 0} = = J \ begin \ } 0 & 0 & 0 & 0 & 0 & 0 \\ 0 & 0 & 1 & 0 & 0 & 0 \\ 0 & 0 & 0 & 0 & 0 & 0 \\ 0 & 0 & 0 & 0 & 1 & 0 \\ 0 & 0 & 0 & 0 & 0 & 1 \\ 0 & 0 & 0 & 0 & 0 & 0 \ end {bmatrix}}}

literature

Gerd Fischer: Lineare Algebra , Vieweg-Verlag, ISBN 3-528-97217-3 .