Fractals/Iterations in the complex plane/Mandelbrot set/mset distortion

This page is about: warped midget, distortion of the island ( part of the Mandelbrot set and parameter plane).

=name = There are many names of mini copies of Mandelbrot set within itself:
 * Small Mandelbrot sets
 * mini Mandelbrot set
 * baby Mandelbrot set
 * baby-brot
 * Bug
 * Island : "word 'island' was introduced by Benoit Mandelbrot in his description of the Mandelbrot set in The Fractal Geometry of Nature" Robert Munafo
 * island mu-molecules
 * embedded copy of the Mandelbrot Set
 * Mandelbrotie
 * Midget
 * minibrot
 * primitive M-copies
 * slightly deformed copies of the original shape
 * Near-copies of the Mandelbrot set within itself

Different names for distortion
 * eccentricity
 * compare with eccentricity of of a conic section is a non-negative real number that uniquely characterizes its shape
 * warping
 * deformation

Names for distorted midgets:
 * warped midget

=Examples=

See also:
 * commons:Category:Near-copies_of_the_Mandelbrot_set_within_itself

Sequence of locations from the elephant valley, with the period doubling ( by Claude Heiland-Allen )

4 	-1.565201668337550811e-01+ 1.032247108922831780e+00 i 	1.697e-02 8 	4.048996651751222142e-01 + 1.458203637665893004e-01 i 	2.743e-03 16 	2.925037532341934199e-01 + 1.492506899834379792e-02 i 	3.484e-04 32 	2.602618199285006706e-01 + 1.667791320926506355e-03 i 	4.113e-05 64 	2.524934589775105209e-01 + 1.971526796077277316e-04 i 	4.920e-06 128 	2.506132008410751344e-01 + 2.396932642510365971e-05 i 	5.997e-07 256 	2.501519680089798192e-01 + 2.954962325906881015e-06 i 	7.398e-08 512 	2.500378219137852631e-01 + 3.668242052764790239e-07 i 	9.185e-09 1024 	2.500094340031833728e-01 + 4.569478652064613658e-08 i 	1.144e-09 2048 	2.500023558032561377e-01 + 5.701985912706845832e-09 i 	1.428e-10 4096 	2.500005886128087162e-01 + 7.121326948562731412e-10 i 	1.783e-11 8192 	2.500001471109009610e-01 + 8.897814201389539302e-11 i 	2.228e-12
 * 1) period	 center 			                radius

List by marcm200 cardioid      angle period p      p<-2p->4p         eccentricity   cardioid center -- 5             177.1             1.35           0.35925922475800742273-0.64251373713854231795*i 6             176.5             1.47           0.4433256333996235532-0.37296241666284651872*i 7             176.1             1.55           0.43237619264199450564-0.22675990443534863039*i 8             175.8             1.52           0.40489966517512215871-0.14582036376658927268*i 10            175.4             1.65           0.35681724849231194474-0.069452865466830299157*i 12            175.1             1.72           0.32558950955066034982-0.038047880934755723414*i 15            174.8             1.79           0.29844800890399547644-0.018383367322073254635*i 17            174.7             1.80           0.28756611704687790043-0.012281055409848253349*i 21            174.6             1.84           0.27436979919551240936-0.0062585874913430950342*i 25            174.5             1.87           0.2652783219046058732 -0.0037120599898783183101*i 31            174.4             1.90           0.26095224231422198269-0.0018410978175303128503*i 43            174.34            1.91           0.2556052938434967281 -0.00066797029763820438275*i

Locations:
 * 0,25000102515011806826817597033225524583655 + 0,0000000016387052819136931666219461i Zoom = 6,871947673*(10^10) so radius = 0.14556040756914119* 10^{-10}
 * 0.2925294 + 0.0149698 i @ 0.0006675
 * c = 0.292503753234193 -0.014925068998344i period = 16,  size of image +0.0005
 * by marcm200
 * period 7 c =0.43237619264199450564-0.22675990443534863039i
 * period 14 c=0.4325688150887696537-0.22873440581356344059i
 * period 28 c=0.43266973566541755414-0.22933968667591089763i

=Self-similarity=

The Mandelbrot set is self-similar under magnification in the neighborhoods of the Misiurewicz points. It is also conjectured to be self-similar around generalized Feigenbaum points (e.g., −1.401155 or −0.1528 + 1.0397i), in the sense of converging to a limit set. The Mandelbrot set in general is not strictly self-similar but it is quasi-self-similar, as small slightly different versions of itself can be found at arbitrarily small scales. These little copies of the Mandelbrot set are all slightly different, mostly because of the thin threads connecting them to the main body of the set.

"this combination of familiarity (small copies of the Mandelbrot set) and novelty (subtly distorted, differently decorated) that make the Mandelbrot set much more interesting than the fractals generated by IFS."

=Q&A=

are they exact copies?
They are:
 * not exact copies
 * slightly deformed copies
 * approximately self-similar copies
 * quasiconformally equivalent to the whole Mandelbrot set
 * quasi-self-similar
 * Baby Mandelbrot Sets are Not Exact Self Similar. A baby Mandelbrot sets are homeomorphic to the original one

Why does the Mandelbrot set contain copies of itself?
Why does the Mandelbrot set contain (slightly deformed) copies of itself?
 * "renormalization explains why the baby Mandelbrot set appears: all of the quadratic polynomials in a baby Mandelbrot set renormalize and all renormalize in essentially the same way."
 * "the fractal is a reflection of reflections of reflections ..."
 * "iteration creates complexity. Mandelbrot set is based on checkin behaviour of infinite sequences. The behaviour of that sequences is very complex. In fact, it may be chaotic. We are in the presence of sensitive dependence on initial conditions (a.k.a. the butterfly effect.)"
 * "While the process is very simple, the iterative nature of the process leads to very different results depending on the point on the complex plane at which you start."

Why there are copies of Mandelbrot set in other fractals ?
The Mandelbrot set is universal so it can be find in:
 * an iterated complex mapping
 * the bifurcation locus for a parametrized family of holomorphic functions: rational families of functions, transcendental families
 * the bifurcation locus of any holomorphic family of rational maps
 * quadratic-like maps of Douady and Hubbard

How to describe minibrot ?
Measures
 * period of main pseudocardioid
 * center of main pseudocardioid
 * window ( radius and center) of parameter plane
 * angles of external rays that land on cusp of the pseudocardiod
 * size of main pseudocardioid
 * orientation
 * distortion

Size and orientation
Scaling for period-n windows of chaotic dynamical systems
 * Windows of periodicity scaling by Evgeny Demidov
 * J.A.Yorke, C.Grebogi, E.Ott, and L.Tedeschini-Lalli  "Scaling Behavior of Windows in Dissipative Dynamical Systems" Phys.Rev.Lett. 54, 1095 (1985)
 * B.R.Hunt, E.Ott Structure in the Parameter Dependence of Order and Chaos for the Quadratic Map  J.Phys.A 30 (1997), 7067.
 * Deriving the size estimate by Claude Heiland-Allen
 * approximate selfsimilarity by Claude Heiland-Allen
 * m-island-zoom.c from mandelbrot-graphics library by Claude Heiland-Allen

The formula for the size and orientation:

$$ r = \frac{1}{\beta \Lambda_p^2}$$ Input and related values:
 * nucleus $$c$$ of a minibrot's main pseudocardioid
 * period $$p$$ of a minibrot's main pseudocardioid
 * $$\beta $$
 * $$ \Lambda_n $$
 * $$\lambda_n $$

Output:
 * complex valued size and orientation estimation r ( complex number). To compute it just use arg and abs on the result

where

$$z_1 = 0 ; z_{n+1} = z_n^2 + c $$

$$\lambda_n = 2 z_n $$

$$ \Lambda_n =\lambda_2 \lambda_3 \cdots \lambda_n $$ $$\beta = 1 + \Lambda_2^{-1} + \Lambda_3^{-1} + \dots + \Lambda_p^{-1} $$

How to use it ?

"if the nucleus of the baby is c and the complex size is r, there is another miniature copy near the baby around $$c+rc$$ with size approximately $$r^2$$" 	Claude Heiland-Allen Example minibrots:
 * period 3 near −2
 * period 4 near i
 * period 5 near −1.5+0.5i

See also c function m_size from mandelbrot-numerics library by Claude Heiland-Allen

area
The area $$A$$ of the island of period p+1 is approximated by the formula by Robert Munafo:

$$A_{p+1} \approx 0.05 \frac{sin^2(\frac{\pi}{p})}{p^4}$$

How to measure the distorsion ?
Measure
 * express these in terms of the derivatives of the iteration at the preimage of 0
 * the ratios of radii of the satellites to the main cardioid
 * angular positions of secondary ( child) components
 * in degrees(or radians) because the parts of the minibrot are simply rotated ( conformal transformations )
 * the ratio of two distances to the cusp
 * "Warped midgets in the Mandelbrot set have been measured, using an algorithm that allows the positions of the head, and cardioid atoms (north and south) of any midget to be found, once one has placed the cursor on the computer terminal somewhere inside any midget. We describe two distortions of midgets: linear distortions and angular distortions. When the north and south angles are plotted in the north/south angle plane, families of points are formed. The angle and distance measures of warped midgets from the Sea Horse Valley of the Mandelbrot set and from other sea horse valleys of midgets, whether on the Spike or on tendrils above atoms, all fall closely together in one part of the north/south plane. Measures of warped midgets from tendrils above the major atoms on the surface of the Cardioid fall closely together in another part of the north/south plane. This different way of looking at the Mandelbrot set offers an interesting way of studying the distortions of midgets." A. G. Davis Philip, Michael Frame, Adam Robucci: Warped midgets in the Mandelbrot set. Computers & Graphics 18(2): 239-248 (1994)

eccentricity of the pseudocardioid
The eccentricity of the pseudocardioid was calculated in a geometrical manner and defined as the ratio of two distances from the cusp to the (to do )

$$ ecc = \frac{cusp_B}{cusp_A}$$

position of the child

 * 2 components :
 * parent ( pseudocardioid with period = p ) = p-componenent
 * child ( pseudocircle with period = 2*p) = 2p-component
 * two lines inside parent (pseudocardioid)
 * axis of the lower part of the parent (pseudocardioid) = line thru 2 points: nucleus and cusp of pseudocardioid = lower axis
 * axis of the upper part of the parent = line thru 2 points: nucleus and root point ( between child and parent components) = upper axis
 * angle between lines measured in turns
 * it is 0 for no distortion = all 3 points are on the same line ( like in case of whole M-set with main cardioid as a parent and period 2 component as a child componenent)
 * it is > 0 for distortion

In mathematical language, the slope m of the line through 2 points
 * $$ z_1 = x_1 + y_1*i$$
 * $$ z_2 = x_2 + y_2*i$$

is


 * $$m=\frac{y_2-y_1}{x_2-x_1}.$$

Angle between two lines of slope $$m_1$$ and $$m_2$$ is

$$ \tan^{-1}\dfrac{m_1 - m_2}{1+m_1 m_2} $$

Here is c function

How distorted can a minibrot be?
What is maxima distortion of minibrot ?

How to find minibrot ?

 * locate = find

How to find distorted minibrot ?

 * using mandelbrot-graphics library and program : m-warped-midgets

What is the relation between distortion and other measures of the island ?

 * the eccentricity grows with increasing period, but not linearly, not even monotone.
 * the biggest island of the wake is the most distorted. The period of the biggest minibrot in the m/n wake is  n+1

=See also=
 * How to find the angles of external rays that land on the root point of any Mandelbrot set's component which is not accessible from main cardioid ( M0) by a finite number of boundary crossing ?

=References=