Let (R, M, φ) be a global dynamical system, with R the real numbers, M the phase space and φ the evolution function. Let γ be a periodic orbit through a point p and S be a local differentiable and transversal section of φ through p, called a Poincaré section through p.

Given an open and connected neighborhood ${\displaystyle U\subset S}$  of p, a function

${\displaystyle P:U\to S}$ 

is called Poincaré map for the orbit γ on the Poincaré section S through the point p if

• P(p) = p
• P(U) is a neighborhood of p and P:U → P(U) is a diffeomorphism
• for every point x in U, the positive semi-orbit of x intersects S for the first time at P(x)

Consider the following system of differential equations in polar coordinates, ${\displaystyle (\theta ,r)\in \mathbb {S} ^{1}\times \mathbb {R} ^{+}}$ :

${\displaystyle {\begin{cases}{\dot {\theta }}=1\\{\dot {r}}=(1-r^{2})r\end{cases}}}$ 

The flow of the system can be obtained by integrating the equation: for the ${\displaystyle \theta }$  component we simply have ${\displaystyle \theta (t)=\theta _{0}+t}$  while for the ${\displaystyle r}$  component we need to separate the variables and integrate:

${\displaystyle \int {\frac {1}{(1-r^{2})r}}dr=\int dt\Longrightarrow \log \left({\frac {r}{\sqrt {1-r^{2}}}}\right)=t+c}$ 

Inverting last expression gives

${\displaystyle r(t)={\sqrt {\frac {e^{2(t+c)}}{1+e^{2(t+c)}}}}}$ 

and since

${\displaystyle r(0)={\sqrt {\frac {e^{2c}}{1+e^{2c}}}}}$ 

we find

${\displaystyle r(t)={\sqrt {\frac {e^{2t}r_{0}^{2}}{1+r_{0}^{2}(e^{2t}-1)}}}={\sqrt {\frac {1}{1+e^{-2t}\left({\frac {1}{r_{0}^{2}}}-1\right)}}}}$ 

The flow of the system is therefore

${\displaystyle \Phi _{t}(\theta ,r)=\left(\theta +t,{\sqrt {\frac {1}{1+e^{-2t}\left({\frac {1}{r_{0}^{2}}}-1\right)}}}\right)}$ 

The behaviour of the flow is the following:

• The angle ${\displaystyle \theta }$  increases monotonically and at constant rate.
• The radius ${\displaystyle r}$  tends to the equilibrium ${\displaystyle {\bar {r}}=1}$  for every value.

Therefore, the solution with initial data ${\displaystyle (\theta _{0},r_{0}\neq 1)}$  draws a spiral that tends towards the radius 1 circle.

We can take as Poincaré section for this flow the positive horizontal axis, namely ${\displaystyle \Sigma =\{(\theta ,r)\ :\ \theta =0\}}$ : obviously we can use ${\displaystyle r}$  as coordinate on the section. Every point in ${\displaystyle \Sigma }$  returns to the section after a time ${\displaystyle t=2\pi }$  (this can be understood by looking at the evolution of the angle): we can take as Poincaré map the restriction of ${\displaystyle \Phi }$  to the section ${\displaystyle \Sigma }$  computed at the time ${\displaystyle 2\pi }$ , ${\displaystyle \Phi _{2\pi }|_{\Sigma }}$ . The Poincaré map is therefore :${\displaystyle \Psi (r)={\sqrt {\frac {1}{1+e^{-4\pi }\left({\frac {1}{r^{2}}}-1\right)}}}}$ 

The behaviour of the orbits of the discrete dynamical system ${\displaystyle (\Sigma ,\mathbb {Z} ,\Psi )}$  is the following:

• The point ${\displaystyle r=1}$  is fixed, so ${\displaystyle \Psi ^{n}(1)=1}$  for every ${\displaystyle n}$ .
• Every other point tends monotonically to the equilibrium, ${\displaystyle \Psi ^{n}(z)\to 1}$  for ${\displaystyle n\to \pm \infty }$ .

Poincaré maps can be interpreted as a discrete dynamical system. The stability of a periodic orbit of the original system is closely related to the stability of the fixed point of the corresponding Poincaré map.

Let (R, M, φ) be a differentiable dynamical system with periodic orbit γ through p. Let

${\displaystyle P:U\to S}$ 

be the corresponding Poincaré map through p. We define

${\displaystyle P^{0}:=\operatorname {id} _{U}}$ 

${\displaystyle P^{n+1}:=P\circ P^{n}}$ 

${\displaystyle P^{-n-1}:=P^{-1}\circ P^{-n}}$ 

and

${\displaystyle P(n,x):=P^{n}(x)}$ 

then (Z, U, P) is a discrete dynamical system with state space U and evolution function

${\displaystyle P:\mathbb {Z} \times U\to U.}$ 

Per definition this system has a fixed point at p.

The periodic orbit γ of the continuous dynamical system is stable if and only if the fixed point p of the discrete dynamical system is stable.

The periodic orbit γ of the continuous dynamical system is asymptotically stable if and only if the fixed point p of the discrete dynamical system is asymptotically stable.

• Poincaré recurrence
• Stroboscopic map
• Hénon map
• Recurrence plot
• Mironenko reflecting function
• Invariant measure

• Teschl, Gerald. Ordinary Differential Equations and Dynamical Systems. Providence: American Mathematical Society.

• Shivakumar Jolad, , (2005)