The multiple-spiral medallions are beautiful decorations situated in the proximity of the small copies of the Mandelbrot set. They are composed by an infinity of babies Mandelbrot sets that have external arguments with known structure. In this paper we study the coupling patterns of the external arguments of the baby Mandelbrot sets in multiple-spiral medallions, that is, how these external arguments are grouped in pairs. Based on our experimental data, we obtain that the canonical nonspiral medallions have a nested pairs pattern, the canonical single-spiral medallions have an adjacent pairs pattern, and we conjecture that the canonical double, triple, quadruple-spiral medallions have a 1-nested/adjacent pairs pattern.
1. Introduction
The Mandelbrot set M was discovered by iterating the complex logistic map zn+1=λzn(1-zn) [1]. Two years later Douady and Hubbard created the external arguments theory of the M set, starting from the complex map zn+1=zn2+c [2]. The M set can be defined as the set of c∈C for which the sequence c, c2+c, (c2+c)2+c,… does not tend to ∞. Since the seminal paper of Douady and Hubbard, the M set has been widely studied [3–14], also from a graphical point of view [15–17].
Recently, Wang et al. have studied the generalized M-J sets starting from the complex map zn+1=znα+c,(α>1). They have proved the connectness of the quaternionic M set [18] and studied the structure and the dynamics of generalized M-J sets [19, 20]. They also offer a rendering method based on the escape-time to draw the M set [21] and research on the structural characteristic and the fission-evolution law of additive perturbed generalized M-J sets [22]. Finally, they modify the escape-time method and form the preperiod graphic of the generalized M set [23] and also research on the structural characteristic of the generalized M set perturbed by composing noise of additive and multiplicative [24, 25].
M contains small copies of itself (babies Mandelbrot sets, BMSs) which in turn contain smaller copies of M, and so on ad infinitum. But the M set, as is well known, is not self-similar. Actually, every BMS has its very own pattern of external decorations. There are BMSs with beautiful central symmetry decorations. Some of these decorations are called cauliflowers [26] or embedded Julia sets [27]. Generalizations of the cauliflowers are the multiple-spiral medallions [28].
There is an infinity of BMSs incrusted in the decoration of a multiple-spiral medallion. The external arguments theory of Douady and Hubbard is a valuable tool in order to analyze the Mandelbrot set [29–31]. In this paper, we will study the structure of the multiple-spiral medallions starting from the external arguments of its BMSs. It was conjectured that the pair of binary expansions of the external arguments of the external rays landing at the cusp of the cardioid of a BMS in a multiple-spiral medallion can be written starting from the binary expansions of the external arguments of its “parent” (.p1¯,.p2¯) and its “gene” (.g1¯,.g2¯) [28]. Each one of the binary expansions (.b1¯,.b2¯) of the central BMS of a multiple-spiral medallion can be expressed in the form .b*¯=.p*p*⋯p*g*¯, where .b̅* is .b̅1 or .b̅2, .p̅* is .p̅1 or .p̅2, and .g̅* is .g̅1 or .g̅2. Each one of the binary expansions (.β1¯,.β2¯) of a noncentral BMS of a multiple-spiral medallion can be expressed in the form
.β*¯=.b*p*p*⋯p*︸j¯
where .β̅* is .β̅1 or .β̅2 and j is the level of the BMS inside the medallion. A given level j has 2j BMSs with 2j+1 different binary expansions.
In this paper, we will study the coupling patterns of the external arguments of the BMSs in a multiple-spiral medallion, that is, how these external arguments are grouped in pairs. We will obtain experimentally, with the computer, the coupling patterns in a lot of (non, single, double, triple …)-spiral medallions [28], up to the BMSs of the fourth level, by computing the kneading sequences of the external arguments [9]. When this procedure fails, because more than two external arguments have the same kneading sequence, we will draw the medallion with its external rays in order to obtain the coupling pattern [32]. As is known, in this case we could also use the Bruin-Schleicher algorithm [12]. Taking into account the relatively high periods of the BMSs, the recursive Lavaurs’s algorithm [6] is not useful in this case.
2. Coupling Patterns in the Multiple-Spiral Medallions2.1. Symbolic Binary Expansions
Let us consider the period-4 hyperbolic component located at -0.1565⋯+1.0322⋯i. As is known from Douady and Hubbard [2], this hyperbolic component has the external arguments (3/15,4/15) in rational form and (.0011¯,.0100¯) in binary expansions form. This hyperbolic component is the parent (.p1¯,.p2¯)=(.0011¯,.0100¯) of an infinity of multiple-spiral medallions inserted into its filaments [28]. From here on, we will normally use the binary expansions of the external arguments. The parent is in the wake of the gene (.g1¯,.g2¯)=(.001¯,.010¯), which is a period-3 disc [28]. In the examples of this paper we, will use this parent and this gene due to their low periods.
Now, let us consider the period-27 BMS located at -0.158682143⋯+1.039701715⋯i, which is the central BMS of a double-spiral medallion near the above parent. The binary expansions of the external arguments of the external rays landing at the cusp of the cardioid of this central BMS are (.b1¯,.b2¯)=(.001101000011010000110011010̅,.001101000011010000110100001¯), which can be verified by using the Jung program [15]. Note that we can write, in abbreviated form, (.b1¯,.b2¯)=(.p1p2p1p2p1p1g2¯,.p1p2p1p2p1p2g1¯)=(.p1p2¯2p12g2¯,.p1p2¯3g1¯) that we name the symbolic binary expansions of the central BMS. In general, as it was conjectured in [28], .b*¯=.p*p*⋯p*g*¯.
The former medallion also has notorious noncentral BMSs as, for example, the period-35 one located at -0.15867218⋯+1.03971266⋯i with binary expansions (.β1¯,.β2¯)=(.00110100001101000011001101000110100̅,.00110100001101000011010000101000011¯) and symbolic binary expansions (.β1¯,.β2¯)=(.b1p1p2¯,.b1p2p1¯), which correspond to a second level BMS. In general, as it was conjectured in [28],
.β*¯=.b*p*p*⋯p*︸j¯.
2.2. Final Kneading Sequence
As is known from [9], the kneading sequence K(θ) of an external argument θ is defined as the itinerary of the orbit of θ under angle doubling, where the itinerary is taken with respect to the partition formed by θ/2 and (θ+1)/2. According to [9]
Let (θ1,θ2) be the external arguments of a hyperbolic component, where θ1<θ2. It is known that K(θ1)=K(θ2) with the exception of the last digits 01 and 10. For instance, when (θ1,θ2)=(3/15,4/15), external arguments of a period-4 hyperbolic component, we obtain the kneading sequences K(θ1)=11010¯ and K(θ2)=11001¯, where the three first digits are the same.
Let us consider a multiple-spiral medallion, and let (.b1¯,.b2¯) be the binary expansions of its period-n central BMS. The first n-1 digits of the kneading sequences of .b1¯ and .b2¯ are the same. Let
(.b*p*p*⋯p*︸j¯,.b*p*p*⋯p*︸j¯)
be the symbolic binary expansions of a noncentral BMS of level j of the same medallion. It is evident that the first n-1 digits of the kneading sequences of the external arguments of the noncentral BMS are the same. To compare the kneading sequences corresponding to the BMSs of a given level in a medallion, it is not necessary to handle all the digits of the kneading sequences because the first n-1 digits are the same. In this paper, we will use the final kneading sequences, that is, the kneading sequences without the first n-1 digits, where n is the period of the central BMS of the medallion.
2.3. The Coupling Problem
We name a multiple-spiral medallion by writing the pair of symbolic binary expansions (.b1¯,.b2¯) corresponding to its central BMS. The coupling problem consists in knowing how the external arguments are coupled in pairs in each one of the noncentral BMSs of a multiple-spiral medallion.
Let (.p1¯,.p2¯) be the binary expansions of the parent of the medallion and let .b1p1¯<.b1p2¯<.b2p1¯<.b2p2¯ be the four symbolic binary expansions of the first level BMSs. We can group them in couples in the forms {(.b1p1¯,.b2p2¯),(.b1p2¯,.b2p1¯)} and {(.b1p1¯,.b1p2¯),(.b2p1¯,.b2p2¯)} (see Figure 1). Note that the grouping {(.b1p1¯,.b2p1¯),(.b1p2¯,.b2p2¯)} is not possible because the corresponding external rays intersect. Therefore, in the first level we have N1=2 coupling patterns.
Possible coupling patterns in the first and second levels .b*p*¯ and .b*p*p*¯ corresponding to the noncentral BMSs in a multiple-spiral medallion.
Likewise, let .b1p1p1¯<.b1p1p2¯<.b1p2p1¯<.b1p2p2¯<.b2p1p1¯<.b2p1p2¯<.b2p2p1¯<.b2p2p2¯ be the eight symbolic binary expansions of the second level BMSs of a medallion. In Figure 1, we show the resulting N2=14 coupling patterns by joining the binary expansions of each couple with a straight line.
The number of possible coupling patterns in a given level increases very rapidly with the level. For instance, in the third level we have counted N3=1374 coupling patterns, and Nl≥Nl-1+∑2l-1+12l3i-2 is a low limit of the number of coupling patterns corresponding to the level l.
However, in each level three patterns with a strong symmetry can be found, which we will call the canonical coupling patterns: the nested pairs pattern, the adjacent pairs pattern, and the 1-nested/adjacent pairs pattern (Figure 2). In the following paragraphs, we will locate multiple-spiral medallions with canonical coupling patterns and we will give examples with both the symbolic binary expansions and the complex coordinates of their central BMSs.
3. Coupling Pattern of Canonical Nonspiral Medallions
Let (.p1¯,.p2¯) and (.g1¯,.g2¯) be the parent and the gene of a nonspiral medallion. As is known from [33, 34], the order-i harmonic of the parent located at its main antenna is characterized by the symbolic binary expansions (.p1p2i¯,.p2p1i¯), and the limit when i→∞ is the tip of the main antenna, which is the Misiurewicz point with preperiodic symbolic binary expansions (.p1p2¯,.p2p1¯). As is also known, the nonspiral medallions are located near the tip and outside of the parent [28]. We name canonical nonspiral medallions those whose central BMSs have the symbolic binary expansions (.p1p2ig2¯,.p2p1ig1¯) with i=1,2…. The limit of the nonspiral medallions when i→∞ is the tip of the parent. In Figure 3(b), we can observe the locations of the i=1,2,3,11 canonical nonspiral medallions corresponding to the parent and the gene of Figure 3(a). The locations of the noncentral BMSs of the nonspiral medallion i=11, up to third level, can be seen in Figure 3(c).
Canonical nonspiral medallions. (a) External rays of the parent and the gene. (b) Graphical location of the medallions i=1,2,3 and 11. (c) Detail of the medallion i=11, where the BMSs up to third level are pointed out.
Obviously, a nonspiral medallion has no spiral. However, we include them in the family of multiple-spiral medallions for two reasons. First, because they are located in the filaments of the parent, as the rest of the multiple-spiral medallions; and second, because the symbolic binary expansions of their central BMSs can be obtained in the same manner as the rest of the medallions (see [28, Figure 8]).
In Table 1 the complex coordinates of some canonical nonspiral medallions are given.
Location of canonical nonspiral medallions.
(.p1p2ig2¯,.p2p1ig1¯)
Location
i=1
-0.172595⋯+1.050337⋯i
i=2
-0.1703025⋯+1.0445545⋯i
i=3
-0.16941127⋯+1.04295087⋯i
i=11
-0.16898713353⋯+1.04237025723⋯i
We have experimentally obtained the coupling patterns of the canonical nonspiral medallions of Table 1, starting from the final kneading sequences up to fourth level BMSs. All of these coupling patterns are the nested pairs pattern of Figure 4.
Coupling pattern of the external arguments of the BMSs up to fourth level in a canonical nonspiral medallion. The corresponding final kneading sequences are shown.
4. Coupling Pattern of Canonical Single-Spiral Medallions
The single-spiral medallions are known as “cauliflowers” [14, 26, 33]. Let (.p1¯,.p2¯) and (.g1¯,.g2¯) be the parent and the gene of a single-spiral medallion. As is known from [33, 34], the order-(i-1) antiharmonic of the parent has the binary expansions (.p1i¯,.p2i¯). We will call canonical single-spiral medallions to those whose central BMSs have the symbolic binary expansions (.p1ig1¯,.p2ig2¯) with i=1,2…. These medallions are inserted in the filament of the cusp of the parent, and its limit when i=∞ is this cusp. In Figure 5(b), we can see the locations of the i=1,2,3 canonical single-spiral medallions corresponding to the parent and the gene of Figure 5(a). The locations of the noncentral BMSs in the single-spiral medallion i=14, up to third level, are shown in Figure 5(c).
Canonical single-spiral medallions. (a) External rays of the parent and the gene. (b) Graphical location of the medallions i=1,2 and 3. (c) Detail of the medallion i=14 where the BMSs up to third level are pointed out.
In Table 2, the complex coordinates of some canonical single-spiral medallions are given.
Location of canonical single-spiral medallions.
(.p1ig1¯,.p2ig2¯)
Location
i=1
-0.12749⋯+0.98746⋯i
i=2
-0.143322⋯+1.018962⋯i
i=3
-0.1488893⋯+1.0259091⋯i
i=8
-0.15375614⋯+1.03038322⋯i
i=14
-0.1543869391⋯+1.0308295094⋯i
The coupling pattern of a single-spiral medallion cannot be obtained by using the final kneading sequences since the kneading sequences of more than two of its noncentral BMSs are the same. However, we have two new options. First, we can use the Bruin and Schleicher algorithm to find conjugate external arguments [12]. Second, we can draw the single-spiral medallion with its external rays (in each level j, we have 2j+1 external rays and 2j+1 symbolic binary expansions) and later to assign the correct symbolic binary expansion to each external ray by simple ordering [32]. We have chosen the last option since the drawing of the i=8 canonical single-spiral medallion was already performed in a previous paper (see [32, Figure 7]). Starting from this figure, the coupling pattern of a canonical single-spiral medallion corresponds to the adjacent pairs pattern of Figure 6.
Coupling pattern of the external arguments of the BMSs up to fourth level in a canonical single-spiral medallion.
5. Coupling Pattern of Canonical Double-Spiral Medallions
Let us consider the gene (.g1¯,.g2¯) and the period-n parent (.p1¯,.p2¯) of a double-spiral medallion. As is known from the tuning algorithm [3], the external rays landing at the tangent point of the cardioid of the parent with its period-2n disc have the symbolic binary expansions (.p1p2¯,.p2p1¯). The double-spiral medallions are inserted in the filaments near these external rays, and the structures .p1p2¯ and .p2p1¯ appear in the symbolic binary expansions of the central BMS of a double-spiral medallion. We name canonical double-spiral medallions those whose central BMS have the symbolic binary expansions (.p1p2¯ip12g2¯,.p1p2¯i+1g1¯) and (.p2p1¯i+1g2¯,.p2p1¯ip22g1¯). In Figure 7(b) we can see the locations of the i=1,2 canonical double-spiral medallions corresponding to the parent and the gene of Figure 7(a). The locations of the noncentral BMSs in the double-spiral medallion (.p1p2¯16p12g2¯,.p1p2¯17g1¯), up to third level, are shown in Figure 7(c). In Table 3 the complex coordinates of some canonical double-spiral medallions are given.
Location of canonical double-spiral medallions.
(.p1p2¯ip12g2¯,.p1p2¯i+1g1¯)
Location
i=1
-0.1566489⋯+1.0417901⋯i
i=2
-0.15868214⋯+1.03970171⋯i
i=3
-0.159450890⋯+1.038682639⋯i
i=16
-0.16090253699⋯+1.03660106997⋯i
Canonical double-spiral medallions. (a) External rays of the parent and the gene. (b) Graphical location of the medallions i=1 and 2. (c) Detail of the medallion (.p1p2¯16p12g2¯,.p1p2¯17g1¯) where the BMSs up to third level are pointed out.
The coupling pattern of the canonical double-spiral medallions can be obtained from the final kneading sequences. The result is the 1-nested/adjacent pairs pattern which can be seen in Figure 8.
Coupling pattern of the external arguments of the BMSs up to fourth level in a canonical double-spiral medallion.
6. Coupling Pattern of Canonical High-Order-Spiral Medallions
Let us consider the gene (.g1¯,.g2¯) and the period-n parent (.p1¯,.p2¯) of a triple-spiral medallion. As is known from the tuning algorithm [3], the external rays landing at the tangent point of the cardioid of the parent with its period-3n discs have the binary expansions (.p12p2¯,.p1p2p1¯) and (.p2p1p2¯,.p22p1¯). These structures appear in the symbolic binary expansions of the central BMS of a triple-spiral medallion. In Figure 9(b) we can observe the locations of the i=1,2 canonical triple-spiral medallions (.p12p2¯ip13g2¯,.p12p2¯i+1g1¯) and (.p1p2p1¯i+1g2¯,.p1p2p1¯ip1p22g1¯) corresponding to the parent and the gene of Figure 9(a). The situations of the noncentral BMSs in the canonical triple-spiral medallion (.p12p2¯11p13g2¯,.p12p2¯12g1¯), up to third level, are pointed out in Figure 9(c). In Table 4 the complex coordinates of some canonical triple-spiral medallions are given.
Location of canonical triple-spiral medallions.
(.p1p2p1¯i+1g2¯,.p1p2p1¯ip1p22g1¯)
Location
i=1
-0.1562143⋯+1.0397508⋯i
i=2
-0.15553568⋯+1.03854489⋯i
i=3
-0.155244096⋯+1.038069528⋯i
i=11
-0.1546766523⋯+1.0373581018⋯i
Canonical triple-spiral medallions (.p12p2¯ip13g2¯,.p12p2¯i+1g1¯). (a) External rays of the parent and the gene. (b) Graphical location of the medallions i=1 and 2. (c) Detail of the medallion i=11 where the BMSs up to third level are pointed out.
The coupling pattern of the canonical triple-spiral medallions can be obtained from the final kneading sequences. The result is again the 1-nested/adjacent pairs pattern which can be seen in Figure 8, as in the case of the double-spiral medallions.
We have found canonical high order-spiral medallions in order to see their coupling patterns. In Tables 5, 6, and 7 the complex coordinates of some of these medallions are given.
Location of canonical quadruple-spiral medallions.
(.p12p2p1¯i+1g2¯,.p12p2p1¯ip12p22g1¯)
Location
i=1
-0.152235840⋯+1.036053596⋯i
i=2
-0.1524782284⋯+1.0354175710⋯i
i=3
-0.15255235393⋯+1.03515698018⋯i
i=8
-0.152602024868⋯+1.034789268092⋯i
Location of canonical quintuple-spiral medallions.
(.p13p2p1¯i+1g2¯,.p13p2p1¯ip13p22g1¯)
Location
i=1
-0.15200993⋯+1.03357269⋯i
i=2
-0.152295958⋯+1.033337933⋯i
i=3
-0.1523987430⋯+1.0332321714⋯i
i=6
-0.152493713878⋯+1.033103509887⋯i
Location of canonical 20.tuple-spiral medallions.
(.p118p2p1¯i+1g2¯,.p118p2p1¯ip118p22g1¯)
Location
i=1
-0.15450307968⋯+1.03099364735⋯i
i=2
-0.154507245205⋯+1.030998040742⋯i
i=3
-0.1545092214233⋯+1.0309995721981⋯i
The coupling patterns of canonical quadruple, quintuple and 20.tuple-spiral medallions correspond once again to the 1-nested/adjacent pairs pattern of Figure 8, similarly to the cases of the double and triple-spiral medallions. Therefore, we can conjecture that the canonical n.tuple-spiral medallions (n≥2) have a 1-nested/adjacent pairs pattern.
7. Conclusions
The coupling patterns of the canonical multiple-spiral medallions have been experimentally studied. Two experimental methods have been used to find the coupling patterns: the first one by using the kneading sequences, and the second one by using the handmade drawing of external rays and the later ordering of their external arguments.
Based on the former experimental methods, three coupling patterns are found. The canonical nonspiral medallions have a nested pairs pattern, the canonical single-spiral medallions have an adjacent pairs pattern, and the canonical (double, triple, quadruple, quintuple and 20.tuple)-spiral medallions have a 1-nested/adjacent pairs pattern. Taking into account this last thirst case, we conjecture that any canonical n.tuple-spiral medallion (n≥2) has a 1-nested/adjacent pairs pattern.
Acknowledgments
This work was supported by CDTI in collaboration with Telefónica project SEGUR@ and by CDTI in collaboration with SAC project HESPERIA.
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