Ikeda map

In physics and mathematics, the Ikeda map is a discrete-time dynamical system given by the complex map

${\displaystyle z_{n+1}=A+Bz_{n}e^{i(|z_{n}|^{2}+C)}}$

The trajectories of 2000 random points in an Ikeda map with u = 0.918.

The original map was proposed first by Kensuke Ikeda as a model of light going around across a nonlinear optical resonator (ring cavity containing a nonlinear dielectric medium) in a more general form. It is reduced to the above simplified "normal" form by Ikeda, Daido and Akimoto [1][2] ${\displaystyle z_{n}}$ stands for the electric field inside the resonator at the n-th step of rotation in the resonator, and ${\displaystyle A}$ and ${\displaystyle C}$ are parameters which indicate laser light applied from the outside, and linear phase across the resonator, respectively. In particular the parameter ${\displaystyle B\leq 1}$ is called dissipation parameter characterizing the loss of resonator, and in the limit of ${\displaystyle B=1}$ the Ikeda map becomes a conservative map.

The original Ikeda map is often used in another modified form in order to take the saturation effect of nonlinear dielectric medium into account:

${\displaystyle z_{n+1}=A+Bz_{n}e^{iK/(|z_{n}|^{2}+1)+C}}$

A 2D real example of the above form is:

${\displaystyle x_{n+1}=1+u(x_{n}\cos t_{n}-y_{n}\sin t_{n}),\,}$

${\displaystyle y_{n+1}=u(x_{n}\sin t_{n}+y_{n}\cos t_{n}),\,}$

where u is a parameter and

${\displaystyle t_{n}=0.4-{\frac {6}{1+x_{n}^{2}+y_{n}^{2}}}.}$

For ${\displaystyle u\geq 0.6}$, this system has a chaotic attractor.