- #1
david34
- 3
- 0
I´m having a hard time proving the next result:
Let [itex]T:V→V[/itex] be a linear operator on a finite dimensional vector space [itex]V[/itex] . If [itex]T[/itex] is irreducible then [itex]T[/itex] cyclic.
My definitions are: [itex]T[/itex] is an irreducible linear operator iff [itex]V[/itex] and {[itex]{\vec 0}[/itex]} are the only complementary invariant subspaces.
T is cyclic linear operator iff V is a cyclic vector space (i.e. there is a vector [itex]\vec v ∈ V[/itex] such that [itex]V[/itex] is generated by the set of vectors {[itex]{ \vec v, T(\vec v), T^{2}(\vec v),...}[/itex]}
I was trying to do it by contradiction: suppose [itex]T[/itex] is not a cyclic linar operator then [itex]∀ \vec v ∈ V[/itex] the generated space by the set {[itex]{ \vec v, T(\vec v), T^{2}(\vec v),...}[/itex]} is not equal to [itex]V[/itex] also if [itex]\vec v \neq \vec 0[/itex] then [itex]span[/itex] { [itex]\vec v, T(\vec v), T^{2}(\vec v),...[/itex] } is not equal to [itex]{\vec 0}[/itex].
Moreover [itex]span[/itex] {[itex]\vec v, T(\vec v), T^{2}(\vec v),...[/itex] } is invariant (I´ve already proven it); also I know that every subspace has a complement that is : [itex]∃ W[/itex] subspace of V such that [itex]W ⊕ span[/itex]{[itex]\vec v, T(\vec v), T^{2}(\vec v),...[/itex]} [itex]= V[/itex]
Then I think a just need to prove that the complementary subspace [itex]W[/itex] is invariant that is : [itex]T(W)⊆ W[/itex] but this is the part that I´m having trouble.
Any comment, suggestion, hint would be highly appreciated
Let [itex]T:V→V[/itex] be a linear operator on a finite dimensional vector space [itex]V[/itex] . If [itex]T[/itex] is irreducible then [itex]T[/itex] cyclic.
My definitions are: [itex]T[/itex] is an irreducible linear operator iff [itex]V[/itex] and {[itex]{\vec 0}[/itex]} are the only complementary invariant subspaces.
T is cyclic linear operator iff V is a cyclic vector space (i.e. there is a vector [itex]\vec v ∈ V[/itex] such that [itex]V[/itex] is generated by the set of vectors {[itex]{ \vec v, T(\vec v), T^{2}(\vec v),...}[/itex]}
I was trying to do it by contradiction: suppose [itex]T[/itex] is not a cyclic linar operator then [itex]∀ \vec v ∈ V[/itex] the generated space by the set {[itex]{ \vec v, T(\vec v), T^{2}(\vec v),...}[/itex]} is not equal to [itex]V[/itex] also if [itex]\vec v \neq \vec 0[/itex] then [itex]span[/itex] { [itex]\vec v, T(\vec v), T^{2}(\vec v),...[/itex] } is not equal to [itex]{\vec 0}[/itex].
Moreover [itex]span[/itex] {[itex]\vec v, T(\vec v), T^{2}(\vec v),...[/itex] } is invariant (I´ve already proven it); also I know that every subspace has a complement that is : [itex]∃ W[/itex] subspace of V such that [itex]W ⊕ span[/itex]{[itex]\vec v, T(\vec v), T^{2}(\vec v),...[/itex]} [itex]= V[/itex]
Then I think a just need to prove that the complementary subspace [itex]W[/itex] is invariant that is : [itex]T(W)⊆ W[/itex] but this is the part that I´m having trouble.
Any comment, suggestion, hint would be highly appreciated