Relative superior mandelbrot and julia sets for integer and non integer values

IJRET: International Journal of Research in Engineering and Technology ISSN: 2319-1163
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Volume: 01 Issue: 02 | Oct-2012, Available @ http://www.ijret.org 139
RELATIVE SUPERIOR MANDELBROT SETS AND RELATIVE
SUPERIOR JULIA SETS FOR INTEGER AND NON-INTEGER VALUES
Rajeshri Rana1
, Yashwant Singh Chauhan2
1
Assistant Professor, Mathematics, 2
Assistant Professor, CSED/MCA, G. B. Pant Engineering College, Pauri-Garhwal,
Uttarakhand, India, ranarajeshri@rediffmail, yashwant.s.chauhan@gmail.com
Abstract
The fractals generated from the self-squared function,
2
z z c  where z and c are complex quantities have been studied
extensively in the literature. This paper studies the transformation of the function , 2n
z z c n   and analyzed the z plane and
c plane fractal images generated from the iteration of these functions using Ishikawa iteration for integer and non-integer values.
Also, we explored the drastic changes that occurred in the visual characteristics of the images from n = integer value to n = non
integer value.
Keywords: Complex dynamics, Relative Superior Julia set, Relative Superior Mandelbrot set.
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1. INTRODUCTION
“Fractal” is a word invented by Mandelbrot to bring together
under the one heading, a large class of objects that have
played an historical role in the development of pure
mathematics. A great revolution of ideas separates the
classical mathematics of the 19th century from the modern
mathematics of the 20th. Classical mathematics had its roots
in the regular geometric structures of Euclid and the
continuously evolving dynamics of Newton. Modern
mathematics began with Cantor‟s set theory and Piano‟s
space-filling curve. Historically, the revolution was forced by
the discovery of mathematical structures that did not fit the
patterns of Euclid and Newton. These new structures were
regarded as „pathological,‟... as a „gallery of monsters,‟ kin to
the cubist painting and atonal music that were upsetting
established standards of taste in the arts at about the same
time. The mathematicians who created the monsters regarded
them as important in showing that the world of pure
mathematics contains a richness of possibilities going far
beyond the simple structures that they saw in Nature.
Twentieth-century mathematics flowered in the belief that it
had transcended completely the limitations imposed by its
natural origins.
Perhaps the Mandelbrot set [12] is the most popular object in
fractal theory. It is believed that it is not only the most
beautiful object, which has been made visible but the most
complex also. This object was given by Benoit B. Mandelbrot
in 1979 and has been the subject of intense research right from
its advent. It is known to us that all the complex quadratic
functions are topologically conjugate to the complex quadratic
function Q(z) = z2 + c. Recall that every Julia set for Q(z)= z2
+ c is either connected or totally disconnected. The
Mandelbrot set works as a locator for the two types of Julia
sets. Each point in the Mandelbrot set represents a c-value for
which the Julia set is connected and each point in its
complement represents a c-value for which the Julia set is
totally disconnected [12].
The fractals generated from the self-squared function,
2
z z c  where z and c are complex quantities, have
been studied extensively in the literature[5, 6, 7,8 & 11].
Recently, the generalized transformation function
n
z z c
  for positive integer values of n has been
considered by K. W. Shirriff [11]. The z plane fractal images
for the function 1 nnz z c
   for positive and negative,
both integer and non-integer values of n have been
presented by Gujar et al. along with some conjectures about
their visual characteristics[6, 7]. In this paper, we have
considered the transformation of the
function
, 2n
z z c n   and analyzed the z plane and c
plane fractal images generated from the iteration of these
functions using Ishikawa iteration for integer and non-integer
values. Also, we explored the drastic changes that occurred
in the visual characteristics of the images from n = integer
value to n = non integer value[2, 3 &15].
2. PRELIMINARIES
Let
{ : 1,2,3,4.........}nz n 
, denoted by
{ }nz
be a
sequence of complex numbers. Then, we say
n
n
Lim z


if,
for given M > 0, there exists N > 0, such that for all n > N, we

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must have
| |nz M . Thus all the values of nz , lies outside a
circle of radius M, for sufficiently large values of n.
Let
1 2 1 0
0 1 2 1 0( ) ............... ; 0n n n
n nQ z a z a z a z a z a z a 
       be a
polynomial of degree n, where 2n . The coefficients are
allowed to be complex numbers. In other words, it follows
that
2
( )cQ z z c  .
Definition 2.1[4]:Let X be a nonempty set and :f X X .
For any point 0x X , the Picard‟s orbit is defined as the set
of iterates of a point 0x , that is;
0 1( , ) { ; ( ), 1,2,3.....}n n nO f x x x f x n  
.
In functional dynamics, we have existence of two different
types of points. Points that leave the interval after a finite
number are in stable set of infinity. Points that never leave the
interval after any number of iterations have bounded orbits.
So, an orbit is bounded if there exists a positive real number,
such that the modulus of every point in the orbit is less than
this number.
The collection of points that are bounded, i.e. there exists M,
such that
| ( ) |n
Q z M , for all n, is called as a prisoner set
while the collection of points that are in the stable set of
infinity is called the escape set. Hence, the boundary of the
prisoner set is simultaneously the boundary of escape set and
that is Mandelbrot set for Q.
Definition 2.2[4]:The Mandelbrot set M for the quadratic
2
( )cQ z z c  is defined as the collection of all c C for
which the orbit of the point 0 is bounded, that is
{ :{ (0)}; 0,1,2,...... }n
cM c C Q n isbounded  
. An equivalent
formulation is
{ :{ (0) }n
cM c C Q doesnottendto asn    .
We choose the initial point 0, as 0 is the only critical point of
cQ
.
3. ISHIKAWA ITERATION FOR RELATIVE
SUPERIOR MANDELBROT SETS AND
RELATIVE SUPERIOR JULIA SETS
Let X be a subset of real or complex numbers
and
:f X X . For 0x X
, we construct the
sequences
{ }nx
and
{ }ny
in X in the following manner:
0 0 0 0 0( ) (1 )y s f x s x   
1 1 1 1 1( ) (1 )y s f x s x    ...
( ) (1 )n n n n ny s f x s x   
where
0 1ns  and
 ns
is convergent to non zero number
and
1 0 0 0 0( ) (1 )x s f y s x  
2 1 1 1 1( ) (1 )x s f y s x   ...
1 1 1 1( ) (1 )n n n n nx s f y s x     
where
0 1ns  and
 ns
is convergent to non zero
number[9].
Definition 3.1[2,15]: The sequences
 nx
and
 ny
constructed above is called Ishikawa sequences of
iterations or relative superior sequences of iterates. We denote
it by 0( , , , )n nRSO x s s t
.
Notice that 0( , , , )n nRSO x s s t
with ns
=1 is
0( , , )nRSO x s t i.e. Mann‟s orbit and if we place
1n ns s 
then 0( , , , )n nRSO x s s t
reduces to 0( , )O x t
.
We remark that Ishikawa orbit
0( , , , )n nRSO x s s t
with
1/ 2ns  is Relative Superior orbit.
Now we define Mandelbrot sets for function with respect to
Ishikawa iterates. We call them as Relative Superior
Mandelbrot sets.
Definition 3.2[15]: Relative Superior Mandelbrot set SM for
the function of the form
( ) n
cQ z z c  , where n = 1, 2, 3,
4… is defined as the collection of c C for which the orbit of
0 is bounded i.e.
{ : (0): 0,1,2...}k
cRSM c C Q k  
is bounded.
Definition 3.3[2]: The set of points SK whose orbits are
bounded under Relative superior iteration of function Q(z) is
called Relative Superior Julia sets. Relative Superior Julia set
of Q is boundary of Julia set RSK.
3.4 Escape Criterion[2,15]: Fractals have been generated
from , 2n
z z c n   and
1
( )n
z z c 
  , 2n 
using escape-time techniques, for example by Gujar etal.[6, 7]

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and Glynn [8]. We have used in this paper escape time criteria
of Relative Superior Ishikawa iterates for both of these
functions.
Escape Criterion for Quadratics: Suppose
that| | max{| |,2/ ,2/ }z c s s , then
| | (1 ) | |n
nz z  and
| |nz  as n .So, | | | |z c and | | 2/z s as well
as| | 2 /z s shows the escape criteria for quadratics.
Escape Criterion for Cubics: Suppose
1/2 1/2
| | max{| |,(| | 2/ ) ,(| | 2/ ) }z b a s a s   then
| |nz  
as n . This gives an escape criterion for cubic
polynomials.
General Escape Criterion: Consider
1/ 1/
| | max{| |,(2/ ) ,(2/ ) }n n
z c s s then
| |nz  
as n is the escape criterion. Note that the initial value 0z
should be infinity, since infinity is the critical point
of
1
( )n
z z c 
  . However instead of starting with 0z =
infinity, it is simpler to start with 1z =
c, which yields the
same result. (A critical point of z F(z) c  is a point
where ( ) 0F z  ). The role of critical points is explained in
[1].
4. GENERATION OF FRACTALS
A) Generation Of Fractals For Integer Values:
4.1 Relative Superior Mandelbrot Sets: We generate
Relative Superior Mandelbrot sets. We present here some
Relative Superior Mandelbrot sets for quadratic, cubic and
biquadratic function.
4.11 Relative Superior Mandelbrot Sets for
Quadratic function:
Figure 1: Relative Superior Mandelbrot Set for s=0.1, s'=0.4
4.12 Relative Superior Mandelbrot Sets for Cubic
function:
Figure 2: Relative Superior Mandelbrot Set fo
r s=0.4, s'=0.1
4.13 Relative Superior Mandelbrot Sets for Bi-
quadratic function:

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4.14 Generalization of Relative Superior Mandelbrot
Set
Figure 1: Relative Superior Mandelbrot Set for s=0.1, s'=0.4,
n=19
n=19
4.2 Relative Superior Julia Sets:
We generate Relative Superior Julia sets. We present here
some Relative Superior Julia sets for quadratic, cubic and
4.2.1 Relative Superior Julia Sets for Quadratic
function:
Figure 1: Relative Superior Julia Set for s=0.1, s'=0.4, c=-
20.26+0.097i
Figure 2: Relative Superior Julia Set for s=0.4, s'=0.1,
c=2.1+5.53i
4.22 Relative Superior Julia Sets for Cubic function:
Figure 1: Relative Superior Julia Set for s=0.1, s'=0.4, c = -
1.6+6.7i
Figure 2: Relative Superior Julia Set for s=0.4, s'=0.1, c= -
1+0.5i
4.23 Relative Superior Julia Sets for Bi-quadratic
function:
Figure 1: Relative Superior Julia Set for s=0.1, s'=0.4,
c=2.6+0.0i
Figure 2: Relative Superior Julia Set for s=0.3, s'=0.4, c= -
3.6+0.0i

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B) Generation Of Fractals For Non-Integer Values:
4.3 Relative Superior Mandelbrot Sets: We generate
Relative Superior Mandelbrot sets. We present here some
Relative Superior Mandelbrot sets for quadratic, cubic and
4.31 Relative Superior Mandelbrot Sets for Cubic
function:
n=3.6
n=3.8
4.32 Relative Superior Mandelbrot Sets for Bi-
quadratic function:
n=4.2
n=4.6
1.33Generalization of Relative Superior Mandelbrot Set:
Figure 1: Relative Superior Mandelbrot Set for s=0.4, s‟=0.3,
n=15.8
Figure 2: Relative Superior Mandelbrot Set for s=0.5, s‟=0.4,
n=16.2
4.4 RELATIVE SUPERIOR JULIA SETS:
We generate Relative Superior Julia sets. We present here
some Relative Superior Julia sets for quadratic, cubic and
4.41 Relative Superior Julia Sets for Cubic function:
Figure 1: Relative Superior Julia Set for s=0.5, s'=0.4, n=3.6,
c=0.03488180321+0.02537719055i
c=-0.0442117701+0.03592300032i

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4.42 Relative Superior Julia Sets for Bi-quadratic
function:
Figure 1: Relative Superior Julia Set s=0.8, s'=0.2, n=4.2,
c=0.04015470798+0.03592299963i
c=0.003244373774+0.02010428497i
5. GRAPHS
A) Fixed points of Integer values:
5.1 Fixed points of quadratic polynomial
Figure 1: Orbit of F(z) for (z0=-1.077560973 -0.823761912i
) at s=0.1 and s'=0.4
5.2 Fixed points of Cubic polynomial :
Figure 1: Orbit of F(z) for (z0= 0.14+2.25i) at s=0.4 and
s'=0.1
5.3 Fixed points of biquadratic polynomial :
Fig1: Orbit of F(z) for (z0= -0.118+0.021i) at s=0.4 and s'=0.1
B).Fixed points of Non-Integer values:
5.4 Fixed points of Cubic Polynomial :
Figure 1: Orbit of F(z) for s=0.8, s'=0.2, n=3.6,
c=0.006067272682+0

__________________________________________________________________________________________
c=0.03488180321-0.01680604855
5.5 Fixed points of biquadratic polynomial :
c=0.003244373774+0.02010428497i
Figure 2: Orbit of F(z) for s=0.5, s'=0.4, n=4.8, c=-
0.1125374895-0.0520056533i
6. ANALYSIS
The z plane fractal images for the function 1 nnz z c
  
for positive and negative, both integer and non-integer
values of n have been presented by Gujar et al. [6, 7] along
with some conjectures about their visual characteristics.
Z plane fractals: The geometrical analysis of Relative
Superior Mandelbrot sets for the function
,n
z z c  2n  reveals the following changes when
we move from the positive integer to a positive non integer
value:
Relative Superior Mandelbrot Sets:
 The geometrical analysis of Relative Superior
Mandelbrot for the function , 2n
z z c n   shows
that the stable points of this function in z-plane are black
colored. Here the stable region is bounded by the unstable
region.
 Also, we notice that the number of lobes in the
Relative Superior Mandelbrot sets increases by (n+1) as one
move from an integer to a non integer value nearby the
consecutive next integer. Also, for integer values, the
symmetry is maintained along real axis for even functions
whereas for the odd function, the symmetry is maintained
along both axes but such case does not exists for the non-
integer terms.
 For n=2, there does not exists Relative Superior
Mandelbrot for non-integer function.
 For odd integer (n=3), we see that there are two self
similar lobes initially. As we move to n=3.2, there exists a
small growth between two major lobes, on the left hand side,
thus creating asymmetry along the Y axis, however the
symmetry is retained for the X axis. When the value of n
increases to 3.6, we predicted the emergence of a small
embryonic lobe. This develops more when we move to n=3.8.
The generalization (n= 15) of this result also presents the
same picture of development of embryonic lobe. Thus, the
Relative Superior Mandelbrot sets are symmetrical only about
the real axis.
 For even integer (n= 4), we observe that the size of
the major lobe situated on the left hand side (negative axis) is
increased. In addition, the major lobe appears to be composed
of the two partially overlapping lobes in the form of a
composite lobe (At n=4.2). This composite lobe has two
constituent lobes that are visible to us on the verge of splitting
two major lobes (At n=4.6). The generalization of this result
is obtained for n=16, where the growth of the embryonic lobe
takes place in the same manner. Here also, the Relative
Superior Mandelbrot sets are found symmetrical only about
the real axis.
C plane fractals: The geometrical analysis of Relative
Superior Julia sets for the function ,n
z z c  2n 
reveals the following changes when we move from the
positive integer to a positive non integer value:
Relative Superior Julia Sets:
 Geometrical analysis of the Relative Superior Julia sets of
inverse function for non integer values shows that the
boundary of the fixed point region forms a (n + 2)
hypocycloid instead of (n+1). A hypocycloid is a curve formed
by rolling a smaller circle inside a larger circle and tracing a
fixed point on the circumference of the smaller circle. The

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radius of the outer fixed circle for hypocycloid can be
computed as| | | |n
z z
 , where z satisfies the
condition
1/( 2)
| | n
z n 
 , resulting in a radius
of
/( 2)
( 2) n n
nn  
 . The radius of inner moving circle is
| |n
z
yielding
/( 2)n n
n 
.
 The inverse function for the odd integer (n=3), shows a
thin leg appearing at n=3.6, which gets broaden as self similar
legs at n=3.8. So, with the change from the integer to the non
integer value the symmetry about both X and Y axes, now
changes to only about X axis. Further only the rotational
symmetry is maintained while the reflection symmetry is
loosed at non integer values.
 The Relative Superior Julia sets for the even integer (n=
4), we observe that the size of the major lobe situated on the
left hand side (negative axis) is increased. In addition, the
major lobe appears to be composed of the two partially
overlapping lobes in the form of a composite lobe (At n=4.2).
This composite lobe has two constituent lobes that are visible
to us on the verge of splitting two major lobes (At n=4.6).
Further at n=4.8, an embryonic self similar lobe develops.
Thus the symmetry is maintained only along the X axis for
non integer values.
 The generalization of the results is obtained for odd and
even values of n can be observed for n=15 and n=16, where
the growth of the embryonic lobe takes place in the same
manner. Here the structure resembles to that of a constellation
similar to planetary arrangement with central circular planet
surrounded by satellite like structures. Furthermore, the size of
the central planet reduces as the value of n reduces, while the
satellite structures enlarge and diffuses. On the other hand,
with the increase in the value of n, the central planet size
increases and more satellite structures appears with very small
radius.
 The planetary arrangement with central circular planet
surrounded by satellite like structures describes reflection as
well as rotational symmetry.
 It is also observed for the planetary arrangement with
central circular planet that, the stable region is represented by
light color which surrounds the constellation while the dark
color regions represent the unstable areas. This situation is
reverse of the situation for the fractals of the
function
n
z z c  , 2n  where the stable regions are
bounded by unstable regions.
CONCLUSIONS
In this paper, we have considered the transformation of the
function ,n
z z c  2n  . We mathematically analyzed
the visual characteristics of the fractal images in the
complex z and c planes respectively. The Z plane fractal
images for the function ,n
z z c  2n  showed that the
stable region is bounded by unstable region. Besides this, the
non integer value change brought the embryonic structure in
the form of lobe. On the other hand, the C plane geometrical
analysis of the function ,n
z z c  2n  represented the
planetary type structure comprising of central planet with
satellites. Here non integer value change showed the
embryonic self similar growth in the satellite pattern. Also,
this function exhibits the unstable region embedded within the
stable region.
REFERENCES
[1] B. Branner, “The Mandelbrot Set”, Proceedings of
Symposia in Applied Mathematics39 (1989), 75-105.
[2] Yashwant S Chauhan, Rajeshri Rana and Ashish Negi.
“New Julia Sets of Ishikawa Iterates”, International
Journal of Computer Applications 7(13):34–42,
October 2010. Published By Foundation of Computer
Science. ISBN: 978-93-80746-97-5.
[3] Yashwant S Chauhan, Rajeshri Rana and Ashish Negi.
Article: “Complex Dynamics of Ishikawa Iterates for
Non Integer Values”, International Journal of Computer
Applications 9(2):9–16, November 2010. Published By
Foundation of Computer Science. ISBN: 978-93-
80747-81-4.
[4] Robert L. Devaney, “A First Course in Chaotic
Dynamical Systems: Theory and Experiment”,
Addison-Wesley, 1992. MR1202237.
[5] S. Dhurandar, V. C. Bhavsar and U. G. Gujar, “Analysis
of z-plane fractal images from z z c
  for α <
0”, Computers and Graphics 17, 1 (1993), 89-94.
[6] U. G. Gujar and V. C. Bhavsar, “Fractals from
z z c
  in the Complex c-Plane”, Computers and
Graphics 15, 3 (1991), 441-449.
[7] U. G. Gujar, V. C. Bhavsar and N. Vangala, “Fractals
from z z c
  in the Complex z-Plane”, Computers
and Graphics 16, 1 (1992), 45-49.
[8] E. F. Glynn, “The Evolution of the Gingerbread
Mann”, Computers and Graphics 15,4 (1991), 579-582.
[9] S. Ishikawa, “Fixed points by a new iteration method”,
Proc. Amer. Math. Soc.44 (1974), 147-150.
[10] G. Julia, “Sur 1’ iteration des functions rationnelles”, J
Math Pure Appli. 8 (1918), 737-747
[11] K. W. Shirriff, “An investigation of fractals generated
by n
z z c
  ”, Computers and Graphics 13, 4 (1993),
603-607.
[12] B. B. Mandelbrot, “The Fractal Geometry of Nature”,
W. H. Freeman, New York, 1983.
[13] H. Peitgen and P. H. Richter, “The Beauty of Fractals”,
Springer-Verlag, Berlin, 1986.
[14] C. Pickover, “Computers, Pattern, Chaos, and Beauty”,
St. Martin‟s Press, NewYork, 1990.
[15] Rajeshri Rana, Yashwant S Chauhan and Ashish
Negi. “Non Linear Dynamics of Ishikawa Iteration”,
International Journal of Computer Applications

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7(13):43–49, October 2010. Published By Foundation
of Computer Science. ISBN: 978-93-80746-97-5.
[16] S. T. Welstead and T. L. Cromer, “Coloring
Periodicities of Two-dimensional Mappings”,
Computers and Graphics 13, 4 (1989), 539-543.
BIOGRAPHIES:
Rajeshri Rana Chauhan is presently
serving as Assistant Professor
Mathematics in G. B. Pant Enginneeering
College, Uttrakhand, India. She is the
member of Indian mathematical Society.
As an ardent researcher, she is working in
the field of fixed point theory and its
applications. She has, to her credit many publications in
international and national journals and books.
Yashwant Singh Chauhan is presently
serving as Assistant Professor Computer
Science and Engineering Department in
G. B. Pant Enginneeering College,
Uttrakhand, India. As an eminent
researcher, he is working in the field of
Fractals and its applications. He has, to
his credit many publications in international journal

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