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A double pendulum consists of two pendulums attached end to end.. In physics and mathematics, in the area of dynamical systems, a double pendulum, also known as a chaotic pendulum, is a pendulum with another pendulum attached to its end, forming a simple physical system that exhibits rich dynamic behavior with a strong sensitivity to initial conditions. [1]
A plot of the Lorenz attractor for values r = 28, σ = 10, b = 8 / 3 An animation of a double-rod pendulum at an intermediate energy showing chaotic behavior. Starting the pendulum from a slightly different initial condition would result in a vastly different trajectory. The double-rod pendulum is one of the simplest dynamical systems ...
In mathematics, a chaotic map is a map (an evolution function) that exhibits some sort of chaotic behavior. Maps may be parameterized by a discrete-time or a continuous-time parameter. Maps may be parameterized by a discrete-time or a continuous-time parameter.
The Duffing equation is an example of a dynamical system that exhibits chaotic behavior. Moreover, the Duffing system presents in the frequency response the jump resonance phenomenon that is a sort of frequency hysteresis behaviour.
Pendulum. Inverted pendulum; Double pendulum; Foucault pendulum; Spherical pendulum; Kinematics; Equation of motion; Dynamics (mechanics) Classical mechanics; Isolated physical system. Lagrangian mechanics; Hamiltonian mechanics; Routhian mechanics; Hamilton-Jacobi theory; Appell's equation of motion; Udwadia–Kalaba equation; Celestial ...
When three bodies orbit each other, the resulting dynamical system is chaotic for most initial conditions. Because there are no solvable equations for most three-body systems, the only way to predict the motions of the bodies is to estimate them using numerical methods. The three-body problem is a special case of the n-body problem.
Notice the appearance of a "dotted" zone, a signature of chaotic behavior. Orbits of the standard map for K = 0.6. Orbits of the standard map for K = 0.971635. Orbits of the standard map for K = 1.2. Orbits of the standard map for K = 2.0. The large green region is the main chaotic region of the map. A single orbit of the standard map for K=2.0.
Zaslavskii map with parameters: =, =, =. The Zaslavskii map is a discrete-time dynamical system introduced by George M. Zaslavsky.It is an example of a dynamical system that exhibits chaotic behavior.