Herman ring

In the mathematical discipline known as complex dynamics, the Herman ring is a Fatou component^[1] where the rational function is conformally conjugate to an irrational rotation of the standard annulus.

Formal definition edit

Namely if ƒ possesses a Herman ring U with period p, then there exists a conformal mapping

\phi :U\rightarrow \{\zeta :0<r<|\zeta |<1\}

and an irrational number $\theta$ , such that

\phi \circ f^{\circ p}\circ \phi ^{-1}(\zeta )=e^{2\pi i\theta }\zeta .

So the dynamics on the Herman ring is simple.

Name edit

It was introduced by, and later named after, Michael Herman (1979^[2]) who first found and constructed this type of Fatou component.

Function edit

Polynomials do not have Herman rings.
Rational functions can have Herman rings. According to the result of Shishikura, if a rational function ƒ possesses a Herman ring, then the degree of ƒ is at least 3.
Transcendental entire maps do not have them^[3]
meromorphic functions can possess Herman rings. Herman rings for transcendental meromorphic functions have been studied by T. Nayak. According to a result of Nayak, if there is an omitted value for such a function then Herman rings of period 1 or 2 do not exist. Also, it is proved that if there is only a single pole and at least an omitted value, the function has no Herman ring of any period.

Examples edit

Herman and parabolic basin edit

Here is an example of a rational function which possesses a Herman ring.^[1]

f(z)={\frac {e^{2\pi i\tau }z^{2}(z-4)}{1-4z}}

where $\tau =0.6151732\dots$ such that the rotation number of ƒ on the unit circle is $({\sqrt {5}}-1)/2$ .

The picture shown on the right is the Julia set of ƒ: the curves in the white annulus are the orbits of some points under the iterations of ƒ while the dashed line denotes the unit circle.

There is an example of rational function that possesses a Herman ring, and some periodic parabolic Fatou components at the same time.

A rational function

f_{t,a,b}(z)=e^{2\pi it}z^{3}\,{\frac {1-{\overline {a}}z}{z-a}}\,{\frac {1-{\overline {b}}z}{z-b}}

that possesses a Herman ring and some periodic parabolic Fatou components, where

t=0.6141866\dots ,\,a=1/4,\,b=0.0405353-0.0255082i

such that the rotation number of

f_{t,a,b}

on the unit circle is

({\sqrt {5}}-1)/2

. The image has been rotated.

Period 2 Herman ring edit

Further, there is a rational function which possesses a Herman ring with period 2.

A rational function possesses Herman rings with period 2

Here the expression of this rational function is

g_{a,b,c}(z)={\frac {z^{2}(z-a)}{z-b}}+c,\,

where

{\begin{aligned}a&=0.17021425+0.12612303i,\\b&=0.17115266+0.12592514i,\\c&=-1.18521775-0.16885254i.\end{aligned}}

This example was constructed by quasiconformal surgery^[4] from the quadratic polynomial

h(z)=z^{2}-1-{\frac {e^{{\sqrt {5}}\pi i}}{4}}

which possesses a Siegel disk with period 2. The parameters a, b, c are calculated by trial and error.

Letting

{\begin{aligned}a&=0.14285933+0.06404502i,\\b&=0.14362386+0.06461542i,{\text{ and}}\\c&=-0.18242894-0.81957139i,\end{aligned}}

then the period of one of the Herman ring of g_a,b,c is 3.

Shishikura also given an example:^[5] a rational function which possesses a Herman ring with period 2, but the parameters showed above are different from his.

Period 5 Herman ring edit

So there is a question: How to find the formulas of the rational functions which possess Herman rings with higher period?

This question can be answered (for any period > 0) by using the Mandelbrot set for the rational functions g_a,b,c. The classic Mandelbrot set (for quadratic polynomials) is approximated by iterating the critical point for each such polynomial, and identifying the polynomials for which the iterates of the critical point do not converge to infinity. Similarly a Mandelbrot set can be defined for the set of rational functions g_a,b,c by distinguishing between the values of (a,b,c) in complex 3-space for which all the three critical points (i.e. points where the derivative vanishes) of the function converge to infinity, and the values whose critical points do not all converge to infinity.

For each value of a and b, the Mandelbrot set for g_a,b,ccan be calculated in the plane of complex values c. When a and b are nearly equal, this set approximates the classic Mandelbrot set for quadratic polynomials, because g_a,b,c is equal to x² + c when a=b. In the classic Mandelbrot set, Siegel discs can be approximated by choosing points along the edge of the Mandelbrot set with irrational winding number having continued fraction expansion with bounded denominators. The irrational numbers are of course only approximated in their computer representation. These denominators can be identified by the sequence of nodes along the edge of the Mandelbrot set approaching the point. Similarly, Herman rings can be identified in a Mandelbrot set of rational functions by observing a series of nodes arranged on both sides of a curve, and choosing points along that curve, avoiding the attached nodes, thereby obtaining a desired sequence of denominators in the continued fraction expansion of the rotation number. The following illustrates a planar slice of the Mandelbrot set of g_a,b,c with |a-b| = .0001, and with c centered at a value of c which identifies a 5-cycle of Siegel discs in the classic Mandelbrot set.

Mandelbrot set of the rational function g, in the c-plane, near 5-cycles.

The image above uses a =0.12601278 +.0458649i, b= .12582484 +.045796497i, and is centered at a value of c = 0.3688 -.3578, which is near 5-cycles of Siegel discs in the classic Mandelbrot set. In the above image, a 5-cycle of Herman rings can be approximated by choosing a point c along the above illustrated curve having nodes on both sides, for which g_a,b,c has approximately the desired winding number, using values as follows:

${\begin{aligned}a&=.12601278+.0458649i,\\b&=.12582484+.045796497i,{\text{ and}}\\c&=0.37144067-.35829275i,\end{aligned}}$

The resulting 5-cycle of Herman rings is illustrated below:

Julia set of g showing a period 5 Herman ring.

References edit

^ ^a ^b John Milnor, Dynamics in one complex variable: Third Edition, Annals of Mathematics Studies, 160, Princeton Univ. Press, Princeton, NJ, 2006.
^ Herman, Michael-Robert (1979), "Sur la conjugaison différentiable des difféomorphismes du cercle à des rotations", Publications Mathématiques de l'IHÉS, 49 (49): 5–233, doi:10.1007/BF02684798, ISSN 1618-1913, MR 0538680, S2CID 118356096
^ Omitted Values and Herman rings by Tarakanta Nayak.^{[full citation needed]}
^ Mitsuhiro Shishikura, On the quasiconformal surgery of rational functions. Ann. Sci. Ecole Norm. Sup. (4) 20 (1987), no. 1, 1–29.
^ Mitsuhiro Shishikura, Surgery of complex analytic dynamical systems, in "Dynamical Systems and Nonlinear Oscillations", Ed. by Giko Ikegami, World Scientific Advanced Series in Dynamical Systems, 1, World Scientific, 1986, 93–105.

[dyn-1] John Milnor, Dynamics in one complex variable: Third Edition, Annals of Mathematics Studies, 160, Princeton Univ. Press, Princeton, NJ, 2006.

[2] Herman, Michael-Robert (1979), "Sur la conjugaison différentiable des difféomorphismes du cercle à des rotations", Publications Mathématiques de l'IHÉS, 49 (49): 5–233, doi:10.1007/BF02684798, ISSN 1618-1913, MR 0538680, S2CID 118356096

[3] Omitted Values and Herman rings by Tarakanta Nayak.^{[full citation needed]}

[4] Mitsuhiro Shishikura, On the quasiconformal surgery of rational functions. Ann. Sci. Ecole Norm. Sup. (4) 20 (1987), no. 1, 1–29.

[5] Mitsuhiro Shishikura, Surgery of complex analytic dynamical systems, in "Dynamical Systems and Nonlinear Oscillations", Ed. by Giko Ikegami, World Scientific Advanced Series in Dynamical Systems, 1, World Scientific, 1986, 93–105.

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