Difference between revisions of "Poincaré-Dulac theorem"

Consider a (formal) differential equation in $ n $- variables,

$$ \tag{a1 } \dot{x} = A x + ( \textrm{ higher degree } ) . $$

A collection of eigen values $ ( \lambda _ {1} \dots \lambda _ {n} ) $ is said to be resonant if there is a relation of the form

$$ \lambda _ {r} = m _ {1} \lambda _ {1} + \dots + m _ {n} \lambda _ {n} $$

for some $ r \in \{ 1 \dots n \} $, with $ m _ {i} \in \mathbf N \cup \{ 0 \} $, $ \sum _ {i=} 1 ^ {n} m _ {i} \geq 2 $. The Poincaré theorem on canonical forms for formal differential equations says that if the eigen values of the matrix $ A $ in (a1) are non-resonant, then there is a formal substitution of variables of the form $ y = x+ $( higher degree) which makes (a1) take the form

$$ \tag{a2 } \dot{y} = A y. $$

Part of the Poincaré–Dulac theorem says that there is for any equation of the form (a1) a formal change of variables $ y = x + $( higher degree) which transforms (a1) into an equation of the form

$$ \tag{a3 } \dot{y} = Ay + w( y) , $$

where $ w( y) $ is a power series of which all monomials are resonant. Here a monomial $ y ^ {m} e _ {r} $, where $ e _ {r} $ is the $ r $- th element of the standard basis, is called resonant if $ \lambda _ {r} = m _ {1} \lambda _ {1} + \dots + m _ {n} \lambda _ {n} $, where the $ \lambda _ {i} $ are the eigen values of $ A $.

A point $ \lambda = ( \lambda _ {1} \dots \lambda _ {n} ) \in \mathbf C ^ {n} $( a collection of eigen values) belongs to the Poincaré domain if 0 is not in the convex hull of the $ \lambda _ {1} \dots \lambda _ {n} $; the complementary set of all $ \lambda $ such that $ 0 $ is in the convex hull of the $ \lambda _ {1} \dots \lambda _ {n} $ is called the Siegel domain. The second part of the Poincaré–Dulac theorem now says that if the right-hand side of (a1) is holomorphic and the eigen value set $ ( \lambda _ {1} \dots \lambda _ {n} ) $ of $ A $ is in the Poincaré domain, then there is a holomorphic change of variables $ y = x + $( higher degree) taking (a1) to a canonical form (a3), with $ w( y) $ a polynomial in $ y $ consisting of resonant monomials.

A point $ \lambda \in \mathbf C ^ {n} $ is said to be of type $ ( C, \nu ) $, where $ C $ is a constant, if for all $ r = 1 \dots n $,

$$ \left | \lambda _ {r} - \sum _ { i= } 1 ^ { n } m _ {i} \lambda _ {i} \right | \geq \ C \left ( \sum _ { i= } 1 ^ { n } m _ {i} \right ) ^ {- \nu } . $$

The Siegel theorem says that if the eigen values of $ A $ constitute a vector of type $ ( C, \nu ) $ and (a1) is holomorphic, then in a neighbourhood of zero (a1) is holomorphically equivalent to (a2), i.e. there is a holomorphic change of coordinates taking (a1) to (a2).

In the differentiable ( $ C ^ \infty $-) case there are related results, [a3]. Consider a $ C ^ \infty $ vector field $ X= \sum a ^ {i} ( x) ( \partial / {\partial x ^ {i} } ) $( or the corresponding autonomous system of differential equations $ {\dot{x} } {} ^ {i} = a ^ {i} ( x) $). A critical point of $ X $, i.e. a point $ p $ such that $ a ^ {i} ( p) = 0 $, $ i = 1 \dots n $, is called an elementary critical point

$$ $$

if the real part of each eigen value of the matrix $ ( {\partial a ^ {i} } / {\partial x ^ {j} } ) ( p) $ is non-zero. Let $ X $ be a $ C ^ \infty $ vector field with 0 as an elementary critical point. Then in a neighbourhood of zero, $ X $ decomposes as a sum $ X = S+ N $ of $ C ^ \infty $ vector fields $ S $ and $ N $ satisfying $ [ S, N] = 0 $, and with respect to a suitable coordinate system $ y $, $ S $ is of the form $ S = \sum _ {i,j} c _ {j} ^ {i} y ^ {j} ( \partial / {\partial y _ {j} } ) $ with the matrix $ ( c _ {j} ^ {i} ) $ similar to a diagonal matrix, and the linear part of $ N $ can be represented by a nilpotent matrix (Chen's decomposition theorem). This is a non-linear $ C ^ \infty $ analogue of the decomposition of a matrix into commuting semi-simple and nilpotent parts, cf. Jordan decomposition. Now let $ Y = \sum b ^ {i} ( x) ( \partial / {\partial x ^ {i} } ) $ be a second vector field with 0 as an elementary critical point and let $ {\widehat{a} } {} ^ {i} ( x) $ and $ {\widehat{b} } {} ^ {i} ( x) $ be the Taylor series of $ a ^ {i} ( x) $ and $ b ^ {i} ( x) $ around 0. Then there exists a $ C ^ \infty $ transformation around 0 which carries $ X $ to $ Y $ if and only if there exists a formal transformation which carries the formal vector field $ \sum {\widehat{a} } {} ^ {i} ( x) ( \partial / {\partial x ^ {i} } ) $ to the formal vector field $ \sum {\widehat{b} } {} ^ {i} ( x) ( \partial / {\partial x ^ {i} } ) $.

A $ C ^ \infty $- linearization result due to S. Sternberg says the following [a4], [a5]. If the matrix of linear terms of the equations $ {\dot{x} } {} ^ {i} = \sum a ^ {i} ( x) $, $ a ^ {i} ( 0) = 0 $, is semi-simple and the set of eigen values of this matrix is non-resonant, then there is a $ C ^ \infty $ change of coordinates which linearizes the equations. For results in the $ C ^ {1} $ and $ C ^ {0} $ case cf. [a6], [a7].

The Poincaré–Dulac theorem can be seen as a result on canonical forms of non-linear representations of the one-dimensional nilpotent Lie algebra $ \mathfrak g = \mathbf C $. In this form it generalizes to arbitrary nilpotent Lie algebras. Let $ \mathfrak g $ be a finite-dimensional nilpotent Lie algebra over $ \mathbf C $( cf. Lie algebra, nilpotent). Let $ V _ {n} $ be the Lie algebra of formal vector fields $ \sum a ^ {i} ( x) ( \partial / {\partial x ^ {i} } ) $, $ a ^ {i} ( 0) = 0 $. A formal non-linear representation of $ \mathfrak g $ is a homomorphism $ \rho = \sum _ {n \geq 1 } \rho ^ {n} $ of $ \mathfrak g $ in $ V _ {n} $( where $ \rho ^ {n} $ is the homogeneous part of degree $ n $ in $ \rho $). Such a representation is holomorphic if for each $ X $ the series $ \sum \rho ^ {n} ( X) $ converges in some neighbourhood of $ 0 $. Then $ \rho ^ {1} $ is a linear representation of $ \mathfrak g $, called the linear part of $ \rho $. A formal vector field $ \xi \in V _ {n} $ is called resonant with respect to a linear representation $ \sigma ^ {1} $ of $ \mathfrak g $ if $ [ \sigma ^ {1} ( X), \xi ] = 0 $ for all $ X \in \mathfrak g $. The representation $ \rho $ is normal if each $ \rho ( X) $ is resonant with respect to the semi-simple part (cf. Jordan decomposition) of the linear representation $ \rho ^ {1} $. The Poincaré–Dulac theorem for nilpotent Lie algebras, [a8], now says that $ \rho $ is a holomorphic non-linear representation of a nilpotent Lie algebra $ \mathfrak g $ over $ \mathbf C $, and if $ \rho $ satisfies the Poincaré condition, then $ \rho $ is holomorphically equivalent to a polynomial normal representation. In this setting the Poincaré condition (i.e., belonging to the Poincaré domain) takes the form that $ 0 $ does not belong to the convex hull of the weights (cf. Weight of a representation of a Lie algebra) of the linear part $ \rho ^ {1} $ of $ \rho $.

For rather complete accounts of the Poincaré–Dulac and Siegel theorems cf. [a9], [a10].

In control theory one studies equations $ \dot{x} = f( x, u) $ with a control parameter $ u $; for instance, $ \dot{x} = f( x) + u _ {1} g _ {1} ( x) + \dots + u _ {m} g _ {m} ( x) $. This naturally leads to linearization problems for families of vector fields. In this setting more general notions of equivalence, involving, in particular, feedback laws $ u = h( x, v) $, are also natural (linearization by feedback). A selection of references is [a11]–[a13].

References