Borel functional calculus: Difference between revisions
en>Helpful Pixie Bot m ISBNs (Build KH) |
en>Noix07 |
||
| Line 1: | Line 1: | ||
[[File:Forced Duffing equation Poincaré section.png|300px|thumb|A two dimensional Poincaré section of the forced [[Duffing equation]]]] | |||
In [[mathematics]], particularly in [[dynamical systems]], a '''first recurrence map''' or '''Poincaré map''', named after [[Henri Poincaré]], is the intersection of a [[periodic orbit]] in the [[state space]] of a [[continuous dynamical system]] with a certain lower dimensional subspace, called the '''Poincaré section''', [[Transversality (mathematics)|transversal]] to the [[Flow (mathematics)|flow]] of the system. More precisely, one considers a periodic orbit with initial conditions within a section of the space, which leaves that section afterwards, and observes the point at which this orbit first returns to the section. One then creates a map to send the first point to the second, hence the name first recurrence map. The transversality of the Poincaré section means that periodic orbits starting on the subspace flow through it and not parallel to it. | |||
A Poincaré map can be interpreted as a [[discrete dynamical system]] with a state space that is one dimension smaller than the original continuous dynamical system. Because it preserves many properties of periodic and quasiperiodic orbits of the original system and has a lower dimensional state space it is often used for analyzing the original system. In practice this is not always possible as there is no general method to construct a Poincaré map. | |||
A Poincaré map differs from a [[recurrence plot]] in that space, not time, determines when to plot a point. For instance, the locus of the moon when the earth is at [[perihelion]] is a recurrence plot; the locus of the moon when it passes through the plane perpendicular to the Earth's orbit and passing through the sun and the earth at perihelion is a Poincaré map. It was used by [[Michel Hénon]] to study the motion of stars in a [[galaxy]], because the path of a star projected onto a plane looks like a tangled mess, while the Poincaré map shows the structure more clearly. | |||
== Definition == | |||
[[Image:Poincare map.svg|thumb|230px|In Poincaré section ''S'', the Poincaré map ''P'' projects point ''x'' onto point ''P(x)''.]] | |||
Let ('''R''', ''M'', φ) be a [[global dynamical system]], with '''R''' the [[real number]]s, ''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 '''Poincaré section''' through ''p''. | |||
Given an open and connected [[neighborhood (mathematics)|neighborhood]] ''U'' of ''p'', a [[Function (mathematics)|function]] | |||
:<math>P: U \to S</math> | |||
is called '''Poincaré map''' for orbit γ on the '''Poincaré section''' ''S'' through 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'') | |||
== Poincaré maps and stability analysis == | |||
Poincaré maps can be interpreted as a [[discrete dynamical system]]. The [[stability theory|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 | |||
:<math>P: U \to S</math> | |||
be the corresponding Poincaré map through ''p''. We define | |||
:<math>P^{0} := id_{U}</math> | |||
:<math>P^{n+1} := P \circ P^n</math> | |||
:<math>P^{-n-1} := P^{-1} \circ P^{-n}</math> | |||
and | |||
:<math>P(n, x) := P^{n}(x)</math> | |||
then ('''Z''', ''U'', ''P'') is a discrete dynamical system with state space ''U'' and evolution function | |||
:<math>P: \mathbb{Z} \times U \to U.</math> | |||
Per definition this system has a fixed point at ''p''. | |||
The periodic orbit γ of the continuous dynamical system is [[Stability theory|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. | |||
== See also == | |||
* [[Poincaré recurrence]] | |||
* [[Stroboscopic map]] | |||
* [[Hénon map]] | |||
* [[Recurrence plot]] | |||
* [[Mironenko reflecting function]] | |||
== References == | |||
* {{cite book | |||
| last = Teschl | |||
| given = Gerald | |||
|authorlink=Gerald Teschl | title = Ordinary Differential Equations and Dynamical Systems | |||
| publisher=[[American Mathematical Society]] | |||
| place = [[Providence, Rhode Island|Providence]] | |||
| year = | |||
| url = http://www.mat.univie.ac.at/~gerald/ftp/book-ode/}} | |||
==External links== | |||
* Shivakumar Jolad, ''[http://www.personal.psu.edu/users/s/a/saj169/Poincaremap/Htmlfiles/PoincareMapintro.html Poincare Map and its application to 'Spinning Magnet' problem]'', (2005) | |||
{{DEFAULTSORT:Poincare map}} | |||
[[Category:Dynamical systems]] | |||
Revision as of 20:02, 10 January 2014
In mathematics, particularly in dynamical systems, a first recurrence map or Poincaré map, named after Henri Poincaré, is the intersection of a periodic orbit in the state space of a continuous dynamical system with a certain lower dimensional subspace, called the Poincaré section, transversal to the flow of the system. More precisely, one considers a periodic orbit with initial conditions within a section of the space, which leaves that section afterwards, and observes the point at which this orbit first returns to the section. One then creates a map to send the first point to the second, hence the name first recurrence map. The transversality of the Poincaré section means that periodic orbits starting on the subspace flow through it and not parallel to it.
A Poincaré map can be interpreted as a discrete dynamical system with a state space that is one dimension smaller than the original continuous dynamical system. Because it preserves many properties of periodic and quasiperiodic orbits of the original system and has a lower dimensional state space it is often used for analyzing the original system. In practice this is not always possible as there is no general method to construct a Poincaré map.
A Poincaré map differs from a recurrence plot in that space, not time, determines when to plot a point. For instance, the locus of the moon when the earth is at perihelion is a recurrence plot; the locus of the moon when it passes through the plane perpendicular to the Earth's orbit and passing through the sun and the earth at perihelion is a Poincaré map. It was used by Michel Hénon to study the motion of stars in a galaxy, because the path of a star projected onto a plane looks like a tangled mess, while the Poincaré map shows the structure more clearly.
Definition
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 Poincaré section through p.
Given an open and connected neighborhood U of p, a function
is called Poincaré map for orbit γ on the Poincaré section S through 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)
Poincaré maps and stability analysis
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
be the corresponding Poincaré map through p. We define
and
then (Z, U, P) is a discrete dynamical system with state space U and evolution function
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.
See also
References
- 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.
My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
External links
- Shivakumar Jolad, Poincare Map and its application to 'Spinning Magnet' problem, (2005)