Fractals/Iterations in the complex plane/subwake

How to find the angles of external rays that land on the root point of any Mandelbrot set's component which is accessible from main cardioid ( M0) by a finite number of boundary crossing ?

=Key words=
 * Tuning
 * external ray
 * external angle in the binary number form

=Algorithm = Douady tuning= "The r/s internal ray in $$M_{p/q}$$ is the landing point of external rays $$\theta_\pm(p/q, r/s)$$ obtained from $$\theta_\pm(r/s)$$ by replacing:
 * the digit 0 by repeating block ( of length q) from $$\theta_-(p/q)$$
 * the digit 1 by repeating block ( of length q) from $$\theta_+(p/q)$$ "

"By repeating the same process ( which is known as 'tuning') we can compute the arguments of external rays landing on the boundary of any component which is accessible from  $$M_0$$ by a finite number of boundary crossing." ( Shaun Bullett  )

Douady tuning

=Examples by number of internal angles=



1 angle

 * 1/2 family

2 angles
Angled internal address:

$$ 1 \quad \xrightarrow{p/q}\ q \quad \xrightarrow{r/s}\  s*q$$

describes a way:
 * from center of period 1 hyberbolic component c=0
 * along internal ray for angle p/q toward root point ( p/q-bond )
 * along internal ray for angle r/s toward center ( nucleus) of s*q component of hyperbolic component

where:
 * 1, q,s are periods of hyperbolic components
 * p/q, r/s are internal angles

(1/2, 1/3)
Angled internal address:

$$ 1 \quad \xrightarrow{1/2}\ 2 \quad \xrightarrow{1/3}\  3*2 = 6$$

First compute external angles for p/q = 1/2 and r/s=1/3 wakes :

$$\theta_-(r/s) =\theta_-(1/3) = 0.(001) $$ $$\theta_+(r/s) =\theta_+(1/3) = 0.(010) $$

$$\theta_-(p/q) =\theta_-(1/2) = 0.({\color{Blue}01}) $$ $$\theta_+(p/q) =\theta_+(1/2) = 0.({\color{Red}10}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Using this c program one gets:

input string = sIn = 0.(001) Input Length = 3

replace string for digit 0 = sR0 = 0.(01) Length of sR0 = 2

replace string for digit 1 = sR1 = 0.(10) Length of sR1 = 2 output string in plain form sOut = 0.(010110) Output Length = 6

output string in wikipedia math formula form = sOutf = 0.(\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}) sR0 displayed as a blue and sR1 as a red font

input string = sIn = 0.(010) Input Length = 3

replace string for digit 0 = sR0 = 0.(01) Length of sR0 = 2

replace string for digit 1 = sR1 = 0.(10) Length of sR1 = 2 output string in plain form sOut = 0.(011001) Output Length = 6

output string in wikipedia math formula form = sOutf = 0.(\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}) sR0 displayed as a blue and sR1 as a red font

Result:

$$ \theta_-(p/q, r/s) = \theta_-(1/2, 1/3) = 0.(\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}) $$

$$ \theta_+(p/q, r/s) = \theta_+(1/2, 1/3) = 0.(\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}) $$

Check it with Mandel by Wolf Jung

The angle 22/63  or  p010110 has preperiod = 0  and  period = 6. The conjugate angle is 25/63  or  p011001. The kneading sequence is ABABA*  and the internal address is 1-2-6. The corresponding parameter rays land at the root of a satellite component of period 6. root c = -1.125000000000000 +0.216506350946110 i    period = 10000 It bifurcates from period 2. Center = c = -1.138000666650965 +0.240332401262098 i    period = 6

(1/3,1/25)
Angled internal address:

$$ 1 \quad \xrightarrow{1/3}\ 3 \quad \xrightarrow{1/25}\  3*25 = 75$$

First compute external angles for p/q and r/s wakes :

$$\theta_-(r/s) =\theta_-(1/25) = 0.(0000000000000000000000001) $$ $$\theta_+(r/s) =\theta_+(1/25) = 0.(0000000000000000000000010) $$

$$\theta_-(p/q) =\theta_-(1/3) = 0.({\color{Blue}001}) $$ $$\theta_+(p/q) =\theta_+(1/3) = 0.({\color{Red}010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Using this c program one gets:

input string = sIn = 0.(0000000000000000000000001) Input Length = 25

replace string for digit 0 = sR0 = 0.(001) Length of sR0 = 3

replace string for digit 1 = sR1 = 0.(010) Length of sR1 = 3 output string in plain form sOut = 0.(001001001001001001001001001001001001001001001001001001001001001001001001010) Output Length = 75

output string in wikipedia math formula form = sOutf = 0.(\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red}010})

so the result is:

$$\theta_-(p/q, r/s) =\theta_-(1/3, 1/25) = 0.(\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red}010})$$ $$\theta_+(p/q, r/s) =\theta_+(1/3, 1/25) = 0.(\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red}010}\ {\color{Blue}001}) $$

One can not check it using :
 * program Mandel by Wolf Jung because period 75 exceeds the capacity of Mandel (verison 5.14)
 * knowledgedoor calculator : "There are more than 100000 fractional digits in the new number. We are sorry, but we had to abort the calculation to control the loading on our server"
 * Binary to Decimal converter from xploringbinary because : ***ERROR: invalid characters in input

Floating point decimal value can be computed ( xploringbinary calculator):

0.00100100100100100100100100100100100100100100100100100100100100100100100101001001001001001001001001001001001001001001001001001001001001001001001001010010010010010010010010010010010010010010010010010010010010010010010010010100100100100100100100100100100100100100100100100100100100100100100100100101000100100100100100100100100100100100100100100100100100100100100100100100101000100100100100100100100100100100100100100100100100100100100100100100100101000100100100100100100100100100100100100100100100100100100100100100100100101 = 0.14285714285714285714288739403383051072639529883365108929843563075583153775763414823768752002069960029227911125999721923628800596414804821292109009060239475901499810101181257672784693799296426200506484998155193353019205064595746824097168836030939675768822757699065155639759014879516081816465598503673993914613650270765449619097486325642647311484333459622592887076714167693559186268814330532241007104844902043043591808926221035405535394453260989380025345642382995407618853788922160842622677279223353252746164798736572265625

note that 1/7 = 0.(001) = 0.(142857)= 0.1428571428571428571428571428571428571428571428571428571428571428571428571428571428571428571428571428571428571428...

so the difference is on the 23 decimal position

Using mandelbrot-symbolics:

./m-binangle-to-rational ".(001001001001001001001001001001001001001001001001001001001001001001001001010)" 5396990266136737387082/37778931862957161709567

./m-binangle-to-rational ".(001001001001001001001001001001001001001001001001001001001001001001001010001)" 5396990266136737387089/37778931862957161709567

Or using web interface with input : 1_1/3->3_1/25->75

(1/3,1/2)
Angled internal address:

$$ 1 \quad \xrightarrow{1/3}\ 3 \quad \xrightarrow{1/2}\  6$$

First compute external angles for p/q and r/s wakes :

$$\theta_-(r/s) =\theta_-(1/2) = 0.(01) $$ $$\theta_+(r/s) =\theta_+(1/2) = 0.(10) $$

$$\theta_-(p/q) =\theta_-(1/3) = 0.({\color{Blue}001}) $$ $$\theta_+(p/q) =\theta_+(1/3) = 0.({\color{Red}010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Result is :

$$\theta_-(p/q, r/s) =\theta_-(1/3, 1/2) = 0.({\color{Blue}001}\ {\color{Red}010}) $$ $$\theta_+(p/q, r/s) =\theta_+(1/3, 1/2) = 0.({\color{Red}010}\ {\color{Blue}001}) $$

One can check it using program Mandel by Wolf Jung :

The angle 10/63  or  p001010 has preperiod = 0  and  period = 6. The conjugate angle is 17/63  or  p010001. The kneading sequence is AABAA*  and the internal address is 1-3-6. The corresponding parameter rays are landing at the root of a satellite component of period 6. It is bifurcating from period 3. Do you want to draw the rays and to shift c to the corresponding center?

(1/3,1/3)
First compute external angles for p/q and r/s wakes ( here p/q=r/s) :

$$\theta_-(p/q) =\theta_-(1/3) = 0.({\color{Blue}001}) $$ $$\theta_+(p/q) =\theta_+(1/3) = 0.({\color{Red}010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Result is :

$$\theta_-(p/q, r/s) =\theta_-(1/3, 1/2) = 0.({\color{Blue}001}\ {\color{Blue}001}\ {\color{Red}010}) $$ $$\theta_+(p/q, r/s) =\theta_+(1/3, 1/2) = 0.({\color{Blue}001}\ {\color{Red}010}\ {\color{Blue}001}) $$

One can check it using program Mandel by Wolf Jung :

The angle 74/511  or  p001001010 has preperiod = 0  and  period = 9. The conjugate angle is 81/511  or  p001010001. The kneading sequence is AABAABAA*  and the internal address is 1-3-9. The corresponding parameter rays are landing at the root of a satellite component of period 9. It is bifurcating from period 3. Do you want to draw the rays and to shift c to the corresponding center?

(1/3,1/4)
First compute external angles for p/q and r/s wakes :

$$\theta_-(r/s) =\theta_-(1/4) = 0.(0001) $$ $$\theta_+(r/s) =\theta_+(1/4) = 0.(0010) $$

$$\theta_-(p/q) =\theta_-(1/3) = 0.({\color{Blue}001}) $$ $$\theta_+(p/q) =\theta_+(1/3) = 0.({\color{Red}010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Result is :

$$\theta_-(p/q, r/s) =\theta_-(1/3, 1/4) = 0.({\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red}010}) $$ $$\theta_+(p/q, r/s) =\theta_+(1/3, 1/4) = 0.({\color{Blue}001}\ {\color{Blue}001}\ {\color{Red}010}\ {\color{Blue}001}) $$

One can check it using program Mandel by Wolf Jung :

The angle 586/4095  or  p001001001010 has preperiod = 0  and  period = 12. The conjugate angle is 593/4095  or  p001001010001. The kneading sequence is AABAABAABAA*  and the internal address is 1-3-12. The corresponding parameter rays are landing at the root of a satellite component of period 12. It is bifurcating from period 3. Do you want to draw the rays and to shift c to the corresponding center?

(1/3,3/4)
First compute external angles for p/q and r/s wakes :

$$\theta_-(r/s) =\theta_-(3/4) = 0.(1101) $$ $$\theta_+(r/s) =\theta_+(3/4) = 0.(1110) $$

$$\theta_-(p/q) =\theta_-(1/3) = 0.({\color{Blue}001}) $$ $$\theta_+(p/q) =\theta_+(1/3) = 0.({\color{Red}010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Result is :

$$\theta_-(p/q, r/s) =\theta_-(1/3, 1/2) = 0.({\color{Red}010}\ {\color{Red}010}\ {\color{Blue}001}\ {\color{Red}010}) $$ $$\theta_+(p/q, r/s) =\theta_+(1/3, 1/2) = 0.({\color{Red}010}\ {\color{Red}010}\ {\color{Red}010}\ {\color{Blue}001}) $$

One can check it in program Mandel by Wolf Jung :

The angle 1162/4095  or  p010010001010 has preperiod = 0  and  period = 12. The conjugate angle is 1169/4095  or  p010010010001. The kneading sequence is AABAABAABAA*  and the internal address is 1-3-12. The corresponding parameter rays are landing at the root of a satellite component of period 12. It is bifurcating from period 3. Do you want to draw the rays and to shift c to the corresponding center?

(1/3,1/89)


Angled internal address:

$$ 1 \quad \xrightarrow{1/3}\ 3 \quad \xrightarrow{1/89}\  3*89 = 267$$

(1/4, 1/5)
Input is :

$$(p/q, r/s) = (1/4, 1/5) $$

First compute external angles for p/q and r/s wakes :

$$\theta_-(r/s) =\theta_-(1/5) = 0.(00001) $$ $$\theta_+(r/s) =\theta_+(1/5) = 0.(00010) $$

$$\theta_-(p/q) =\theta_-(1/4) = 0.({\color{Blue}0001}) $$ $$\theta_+(p/q) =\theta_+(1/4) = 0.({\color{Red} 0010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Result is :

$$\theta_-(p/q, r/s) =\theta_-(1/4, 1/5) = 0.({\color{Blue}0001}\ {\color{Blue}0001}\ {\color{Blue}0001}\  {\color{Blue}0001}\ {\color{Red} 0010}) $$ $$\theta_+(p/q, r/s) =\theta_+(1/4, 1/5) = 0.({\color{Blue}0001}\ {\color{Blue}0001}\ {\color{Blue}0001}\  {\color{Red} 0010}\ {\color{Blue}0001}) $$

One can check it using program Mandel by Wolf Jung :

The angle 69906/1048575  or  p00010001000100010010 has preperiod = 0  and  period = 20. The conjugate angle is 69921/1048575  or  p00010001000100100001. The kneading sequence is AAABAAABAAABAAABAAA*  and the internal address is 1-4-20. The corresponding parameter rays are landing at the root of a satellite component of period 20. It is bifurcating from period 4. Do you want to draw the rays and to shift c to the corresponding center?

(4/5, 1/17)
Angled internal address is :
 * $$ 1 \quad \xrightarrow{4/5}\ 5 \quad \xrightarrow{1/17}\  5*17 = 85$$
 * 1-(4/5)-> 5 -(1/17)-> 85

Input is :

$$(p/q, r/s) = (4/5, 1/17) $$

First compute external angles for p/q and r/s wakes :

$$\theta_-(r/s) =\theta_-(1/17) = 0.(00000000000000001) $$ $$\theta_+(r/s) =\theta_+(1/17) = 0.(00000000000000010) $$

$$\theta_-(p/q) =\theta_-(4/5) = 0.({\color{Blue}11101}) $$ $$\theta_+(p/q) =\theta_+(4/5) = 0.({\color{Red}11110 }) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by block of length q from $$\theta_-(p/q) $$
 * digit 1 by block of length q from $$\theta_+(p/q)$$

Result is : $$\theta_-(p/q, r/s) = \theta_-(4/5, 1/17) = 0.(\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Red}11110})$$ $$\theta_+(p/q,r/s) = \theta_+(4/5,1/17) = 0.(\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Red}11110}\ {\color{Blue}11101}) $$

One can not check it using program Mandel by Wolf Jung because period is too big. It gives answers only for period up to 64

One can check it online using web interface by Claude
 * .(1110111101111011110111101111011110111101111011110111101111011110111101111011110111110)
 * .(1110111101111011110111101111011110111101111011110111101111011110111101111011111011101)

(1/2, 1/3, 1/4)
We go thru the list of angles from right to left

First compute (1/3,1/4) wake which will be used as a a new r/s wake :

$$\theta_-(1/3, 1/4) = 0.(001001001010) = \theta_-(r/s) $$ $$\theta_+(1/3, 1/4) = 0.(001001010001) = \theta_+(r/s) $$

After that compute 1/2 wake ( most left), which will be used as a p/q wake :

$$\theta_-(p/q) =\theta_-(1/2) = 0.({\color{Blue}01}) $$ $$\theta_+(p/q) =\theta_+(1/2) = 0.({\color{Red}10}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by repeating block (of length q, color blue) from $$\theta_-(p/q) $$
 * digit 1 by repeating block (of length q, color red) from $$\theta_+(p/q)$$

Result is :

$$\theta_-(1/2, 1/3, 1/4) = 0.({\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01})$$ $$\theta_+(1/2, 1/3, 1/4) = 0.({\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10})$$

in plain text format ( for copy ) :

theta_minus(1/2, 1/3, 1/4) = 0.(010110010110010110011001) theta_plus( 1/2, 1/3, 1/4) = 0.(010110010110010110010110)

One can check this wake in program Mandel by Wolf Jung using ray to point command ( Ctrl+e) :

The angle 5858713/16777215  or  p010110010110010110011001 has preperiod = 0  and  period = 24. The conjugate angle is 5858902/16777215  or  p010110010110011001010110. The kneading sequence is ABABAAABABAAABABAAABABA*  and the internal address is 1-2-6-24. The corresponding parameter rays are landing at the root of a satellite component of period 24. It is bifurcating from period 6. Do you want to draw the rays and to shift c to the corresponding center?

(1/3, 1/4, 1/5)
Input is a list :

(1/3, 1/4, 1/5)

We go thru the list of angles from right to left and divide list into 2 sublists :

$$p/q = 1/3$$ $$r/s = (1/4, 1/5)$$

First compute (1/4,1/5) wake which will be used as a a new r/s wake :

$$\theta_-(1/4, 1/5) = 0.(00010001000100010010) = \theta_-(r/s) $$ $$\theta_+(1/4, 1/5) = 0.(00010001000100100001) = \theta_+(r/s) $$

After that compute 1/3 wake ( most left), which will be used as a p/q wake :

$$\theta_-(p/q) =\theta_-(1/3) = 0.({\color{Blue}001}) $$ $$\theta_+(p/q) =\theta_+(1/3) = 0.({\color{Red} 010}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by repeating block (of length q, color blue) from $$\theta_-(p/q) $$
 * digit 1 by repeating block (of length q, color red) from $$\theta_+(p/q)$$

Result is :

$$\theta_-(1/3, 1/4, 1/5) = 0.({\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001})$$ $$\theta_+(1/3, 1/4, 1/5) = 0.({\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Blue}001}\ {\color{Red} 010})$$

One can check it using program Mandel by Wolf Jung :

The angle 164984615799661137/1152921504606846975  or  p001001001010001001001010001001001010001001001010001001010001 has preperiod = 0  and  period = 60. The conjugate angle is 164984615799689802/1152921504606846975  or  p001001001010001001001010001001001010001001010001001001001010. The kneading sequence is AABAABAABAAAAABAABAABAAAAABAABAABAAAAABAABAABAAAAABAABAABAA*  and the internal address is 1-3-12-60. The corresponding parameter rays are landing at the root of a satellite component of period 60. It is bifurcating from period 12. Do you want to draw the rays and to shift c to the corresponding center?

(1/2, 1/3, 1/4, 1/5)
Input is a list :

(1/2, 1/3, 1/4, 1/5)

so the internal adders should be :

1-2-6-24-120

One can not check it using program Mandel because it is limited to period 64.

We go thru the list of input angles from right to left and divide list into 2 sublists :

$$p/q = 1/2$$ $$r/s = (1/3, 1/4, 1/5)$$

First compute (1/3, 1/4, 1/5) wake which will be used as a a new r/s wake :

$$\theta_-(1/3, 1/4, 1/5) = 0.(001001001010001001001010001001001010001001001010001001010001) = \theta_-(r/s) $$ $$\theta_+(1/3, 1/4, 1/5) = 0.(001001001010001001001010001001001010001001010001001001001010) = \theta_+(r/s) $$

After that compute 1/2 wake ( most left), which will be used as a p/q wake :

$$\theta_-(p/q) =\theta_-(1/2) = 0.({\color{Blue}01}) $$ $$\theta_+(p/q) =\theta_+(1/2) = 0.({\color{Red} 10}) $$

then in $$\theta(r/s) $$ replace :


 * digit 0 by repeating block (of length q, color blue) from $$\theta_-(p/q) $$
 * digit 1 by repeating block (of length q, color red) from $$\theta_+(p/q)$$

Result is ( to check !!!!) :

$$\theta_-(1/2, 1/3, 1/4, 1/5) =0.({\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10})$$

$$\theta_+(1/2, 1/3, 1/4, 1/5) = 0.({\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01}\ {\color{Red}10}\ {\color{Blue}01})$$

theta_minus(1/2, 1/3, 1/4, 1/5) = 0.(010110010110010110011001010110010110010110011001010110010110010110011001010110010110010110011001010110010110011001010110) theta_plus(1/2, 1/3, 1/4, 1/5) = 0.(010110010110010110011001010110010110010110011001010110010110010110011001010110010110011001010110010110010110010110011001)

One can check it visually using book program by Claude Heiland-Allen

size 640 360 view 53 -1.113644126576409e+00 2.5205986428803329e-01 3.9234950282896473e-04 ray_in 2000 .(010110010110010110011001010110010110010110011001010110010110010110011001010110010110011001010110010110010110010110011001) ray_in 2000 .(010110010110010110011001010110010110010110011001010110010110010110011001010110010110010110011001010110010110011001010110) text 53 -1.1152327443471231e+00 2.5276283972645397e-01 1/4 text 53 -1.1136201098499858e+00 2.5201617701965662e-01 1/5 text 53 -1.1152327443471231e+00 2.5276283972645397e-01 1/4 text 53 -1.1138472738947567e+00 2.5348331923684125e-01 24

period 776
1-(1/2)-> 2 -(1/3)-> 6 -(1/2)-> 12 -(1/3)-> 36 -(1/2)-> 72 -(2/3)-> 216 -(1/2)-> 432 -(1/3)-> 1296 -(1/2)-> 2592 -(2/3)-> 7776  -> main misiurewicz point -> right branch

Try mandelbrot-web

period 20
Info from Mandelbrot-web by Claude
 * External Angle ( wiggled external ray )
 * binary = .(00000000001111111111)
 * decimal in Rational form = 1/1025
 * Period = 20
 * Kneading 1111111111000000000★
 * Internal Address : 1→11→12→13→14→15→16→17→18→19→20
 * Landings .00000000001111111111	1/1025 .00000000010000000000	1024/1048575

Angled internal addres:

$$1 \xrightarrow{1/11} 11 \xrightarrow{1/2} 12 \xrightarrow{1/2}  13 \xrightarrow{1/2} 14 \xrightarrow{1/2} 15 \xrightarrow{1/2} 16 \xrightarrow{1/2} 17 \xrightarrow{1/2} 18 \xrightarrow{1/2} 19  \xrightarrow{1/2} 20$$

Info from program Mandel by Wolf Jung
 * The angle 1023/1048575  or  p00000000001111111111
 * has preperiod = 0  and  period = 20.
 * The conjugate angle is 1024/1048575  or  p00000000010000000000.
 * The kneading sequence is AAAAAAAAAABBBBBBBBB*  and
 * the internal address is 1-11-12-13-14-15-16-17-18-19-20.
 * The corresponding parameter rays land at the root of a primitive component of period 20 with center c = 0.329617350093832 +0.042415693708911 i

=Code=

Output:

input string = sIn = 0.(00000000000000010) Input Length = 17

replace string for digit 0 = sR0 = 0.(11101) Length of sR0 = 5

replace string for digit 1 = sR1 = 0.(11110) Length of sR1 = 5 output string in plain form sOut = 0.(1110111101111011110111101111011110111101111011110111101111011110111101111011111011101) Output Length = 85

output string in wikipedia math formula form = sOutf = 0.(\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Blue}11101}\ {\color{Red}11110}\ {\color{Blue}11101}) sR0 displayed as a blue and sR1 as a red font

=See also=
 * islands
 * Mandelbrot symbolics in the browser by 	Claude Heiland-Allen
 * automatically_finding_external_angles by 	Claude Heiland-Allen
 * book program by 	Claude Heiland-Allen
 * Trees of visible components in the Mandelbrot set by Virpi K a u k o - the tree structures of the sublimbs of the Mandelbrot set M, using internal addresses of hyperbolic components

=References=