Dichotomy

The property that for a linear system of ordinary differential equations

$$ \dot{x} = A ( t) x ,\ x \in E ^ {n} ,\ t \geq 0 , $$

with bounded continuous coefficients, there are positive constants $ K $, $ L $, $ \alpha $, and $ \beta $ such that there exists a decomposition $ E ^ {n} = E ^ {m} + E ^ {n-} m $ for which

$$ x ( 0) \in E ^ {m} \Rightarrow \| x ( t) \| \leq K \| x ( \tau ) \| \ \mathop{\rm exp} [ - \alpha ( t - \tau ) ] , $$

$$ t \geq \tau \geq 0 ; $$

$$ x ( 0) \in E ^ {n-} m \Rightarrow \| x ( t) \| \leq L \| x ( \tau ) \| \mathop{\rm exp} [ - \beta ( \tau - t ) ] , $$

$$ \tau \geq t \geq 0 $$

(exponential dichotomy; if $ \alpha = \beta = 0 $, one has ordinary dichotomy). The presence of exponential dichotomy is equivalent to saying that the inhomogeneous system

$$ \dot{x} = A ( t) x + f ( t) $$

has, for any bounded continuous function $ f ( t) $, $ t \geq 0 $, at least one bounded solution on $ [ 0 , \infty ) $[1]. The theory of dichotomy [2], transferred to equations in Banach spaces, is also employed in the study of flows and cascades on smooth manifolds [4].

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