Bendixson–Dulac theorem

In mathematics, the Bendixson–Dulac theorem on dynamical systems states that if there exists a $C^{1}$ function $\varphi (x,y)$ (called the Dulac function) such that the expression

According to Dulac theorem any 2D autonomous system with a periodic orbit has a region with positive and a region with negative divergence inside such orbit. Here represented by red and green regions respectively

{\frac {\partial (\varphi f)}{\partial x}}+{\frac {\partial (\varphi g)}{\partial y}}

has the same sign ( $\neq 0$ ) almost everywhere in a simply connected region of the plane, then the plane autonomous system

{\frac {dx}{dt}}=f(x,y),

{\frac {dy}{dt}}=g(x,y)

has no nonconstant periodic solutions lying entirely within the region.^[1] "Almost everywhere" means everywhere except possibly in a set of measure 0, such as a point or line.

The theorem was first established by Swedish mathematician Ivar Bendixson in 1901 and further refined by French mathematician Henri Dulac in 1923 using Green's theorem.

Proof[edit]

Without loss of generality, let there exist a function $\varphi (x,y)$ such that

{\frac {\partial (\varphi f)}{\partial x}}+{\frac {\partial (\varphi g)}{\partial y}}>0

in simply connected region $R$ . Let $C$ be a closed trajectory of the plane autonomous system in $R$ . Let $D$ be the interior of $C$ . Then by Green's theorem,

{\begin{aligned}&\iint _{D}\left({\frac {\partial (\varphi f)}{\partial x}}+{\frac {\partial (\varphi g)}{\partial y}}\right)\,dx\,dy=\oint _{C}\left(-\varphi g\,dx+\varphi f\,dy\right)\\[6pt]={}&\oint _{C}\varphi \left(-{\dot {y}}\,dx+{\dot {x}}\,dy\right).\end{aligned}}

Because of the constant sign, the left-hand integral in the previous line must evaluate to a positive number. But on $C$ , $dx={\dot {x}}\,dt$ and $dy={\dot {y}}\,dt$ , so the bottom integrand is in fact 0 everywhere and for this reason the right-hand integral evaluates to 0. This is a contradiction, so there can be no such closed trajectory $C$ .

References[edit]

Henri Dulac (1870-1955) was a French mathematician from Fayence

^ Burton, Theodore Allen (2005). Volterra Integral and Differential Equations. Elsevier. p. 318. ISBN 9780444517869.

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[Burton2005-1] Burton, Theodore Allen (2005). Volterra Integral and Differential Equations. Elsevier. p. 318. ISBN 9780444517869.

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