Filled Julia set explained

The filled-in Julia set

of a polynomial is a Julia set and its interior, non-escaping set.

Formal definition

of a polynomial is defined as the set of all points of the dynamical plane that have bounded orbit with respect to $$K(f)\; \backslash overset\; \backslash left\; \backslash$$where: is the set of complex numbers is the -fold composition of with itself = iteration of function

Relation to the Fatou set

The filled-in Julia set is the (absolute) complement of the attractive basin of infinity.$$K(f)\; =\; \backslash mathbb\; \backslash setminus\; A\_(\backslash infty)$$

The attractive basin of infinity is one of the components of the Fatou set.$$A\_(\backslash infty)\; =\; F\_\backslash infty$$

In other words, the filled-in Julia set is the complement of the unbounded Fatou component:$$K(f)\; =\; F\_\backslash infty^C.$$

Relation between Julia, filled-in Julia set and attractive basin of infinity

The Julia set is the common boundary of the filled-in Julia set and the attractive basin of infinity$$J(f)\; =\; \backslash partial\; K(f)\; =\; \backslash partial\; A\_(\backslash infty)$$where:

denotes the attractive basin of infinity = exterior of filled-in Julia set = set of escaping points for

$$A\_(\backslash infty)\; \backslash \; \backslash overset\; \backslash \; \backslash .$$

If the filled-in Julia set has no interior then the Julia set coincides with the filled-in Julia set. This happens when all the critical points of

are pre-periodic. Such critical points are often called Misiurewicz points.

Spine

, which are often denoted by , where is any complex number. In this case, the spine of the filled Julia set is defined as arc between -fixed point and ,$$S\_c\; =\; \backslash left\; [-\; \backslash beta,\; \backslash beta\; \backslash right\; ]$$with such properties:

• spine lies inside

.^[1] This makes sense when is connected and full^[2]

• spine is invariant under 180 degree rotation,
• spine is a finite topological tree,

always belongs to the spine.^[3] -fixed point is a landing point of external ray of angle zero , is landing point of external ray .

Algorithms for constructing the spine:

• detailed version is described by A. Douady^[4]
• Simplified version of algorithm:
  • connect

and within by an arc,

• • when

has empty interior then arc is unique,

• • otherwise take the shortest way that contains

.^[5]

Curve

:$$R\; \backslash overset\; R\_\; \backslash cup\; S\_c\; \backslash cup\; R\_0$$divides dynamical plane into two components.

Names

• airplane^[6]
• Douady rabbit
• dragon
• basilica or San Marco fractal or San Marco dragon
• cauliflower
• dendrite
• Siegel disc

References

1. Peitgen Heinz-Otto, Richter, P.H. : The beauty of fractals: Images of Complex Dynamical Systems. Springer-Verlag 1986. .
2. Bodil Branner : Holomorphic dynamical systems in the complex plane. Department of Mathematics Technical University of Denmark, MAT-Report no. 1996-42.

Notes and References

1. http://www.math.rochester.edu/u/faculty/doug/oldcourses/215s98/lecture10.html Douglas C. Ravenel : External angles in the Mandelbrot set: the work of Douady and Hubbard. University of Rochester
2. http://www.emis.de/journals/EM/expmath/volumes/13/13.1/Milnor.pdf John Milnor : Pasting Together Julia Sets: A Worked Out Example of Mating. Experimental Mathematics Volume 13 (2004)
3. https://arxiv.org/abs/math/9801148 Saaed Zakeri: Biaccessiblility in quadratic Julia sets I: The locally-connected case
4. A. Douady, “Algorithms for computing angles in the Mandelbrot set,” in Chaotic Dynamics and Fractals, M. Barnsley and S. G. Demko, Eds., vol. 2 of Notes and Reports in Mathematics in Science and Engineering, pp. 155–168, Academic Press, Atlanta, Georgia, USA, 1986.
5. [Karen Brucks|K M. Brucks]
6. http://www.math.uni-bonn.de/people/karcher/Julia_Sets.pdf The Mandelbrot Set And Its Associated Julia Sets by Hermann Karcher