Paperfolding sequences, paperfolding curves and local isomorphism

Oger, Francis

doi:10.32917/hmj/1333113006

Cited by 3 publications

(22 citation statements)

References 7 publications

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“…Some results similar to those of [4] are also true for folding sequences and curves in Dekking's sense:…”

Section: Definitions Context and Main Resultssupporting

confidence: 61%

“…We use the definitions, the notations and the results of [4]. In order to simplify some notations, we identify R 2 with C and Z 2 with the set Z + iZ of Gaussian integers.…”

Section: Definitions Context and Main Resultsmentioning

confidence: 99%

“…Many examples of ∞-folding sequences are actually constructed in that way, including the positive folding sequence associated to the dragon curve (see [4,Example 3.13]) and the alternating folding sequence (see [4,Example 3.14]). Some of them are used in the present paper.…”

Section: Definitions Context and Main Resultsmentioning

confidence: 99%

“…The definition of the sets E n (C) for n ∈ N ∪ {∞} and F n (C) for n ∈ N is given in [4]. Their existence follows from [4,Prop. 3.3].…”

Section: Detailed Results and Proofsmentioning

confidence: 99%

“…Remark. According to [4,Theorem 3.10], the covering D given by Theorem 4 is essentially unique: two such coverings only differ by a translation or/and a change in the connections at the E ∞ point.…”

Section: Detailed Results and Proofsmentioning

confidence: 99%

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The number of paperfolding curves in a covering of the plane

Oger¹

2017

Hiroshima Math. J.

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These results complete our previous paper in the same Journal (vol. 42,. Let C be a covering of the plane by disjoint complete folding curves which satisfies the local isomorphism property. We show that C is locally isomorphic to an essentially unique covering generated by an ∞folding curve. We prove that C necessarily consists of 1, 2, 3, 4 or 6 curves. We give examples for each case; the last one is realized if and only if C is generated by the alternating folding curve or one of its successive antiderivatives. We also extend the results of our previous paper to another class of paperfolding curves introduced by M. Dekking.

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“…Some results similar to those of [4] are also true for folding sequences and curves in Dekking's sense:…”

Section: Definitions Context and Main Resultssupporting

confidence: 61%

“…We use the definitions, the notations and the results of [4]. In order to simplify some notations, we identify R 2 with C and Z 2 with the set Z + iZ of Gaussian integers.…”

Section: Definitions Context and Main Resultsmentioning

confidence: 99%

Section: Definitions Context and Main Resultsmentioning

confidence: 99%

“…The definition of the sets E n (C) for n ∈ N ∪ {∞} and F n (C) for n ∈ N is given in [4]. Their existence follows from [4,Prop. 3.3].…”

Section: Detailed Results and Proofsmentioning

confidence: 99%

Section: Detailed Results and Proofsmentioning

confidence: 99%

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The number of paperfolding curves in a covering of the plane

Oger¹

2017

Hiroshima Math. J.

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Peano-Gosper curves and the local isomorphism property

Oger

2017

Preprint

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We consider unbounded curves without endpoints. Isomorphism is equivalence up to translation. Self-avoiding plane-filling curves cannot be periodic, but they can satisfy the local isomorphism property: We obtain a set Ω of coverings of the plane by sets of disjoint self-avoiding nonoriented curves, generalizing the Peano-Gosper curves, such that: 1) each C ∈ Ω satisfies the local isomorphism property; any set of curves locally isomorphic to C belongs to Ω; 2) Ω is the union of 2 ω equivalence classes for the relation "C locally isomorphic to D"; each of them contains 2 ω (resp. 2 ω , 4, 0) isomorphism classes of coverings by 1 (resp. 2, 3, ≥ 4) curves. Each C ∈ Ω gives exactly 2 coverings by sets of oriented curves which satisfy the local isomorphism property. They have opposite orientations.

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Self-avoiding and plane-filling properties for terdragons and other triangular folding curves

Oger

2017

Preprint

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Self-avoiding and plane-filling properties for terdragons and other triangular folding curves Francis OGER ABSTRACT. We consider n-folding triangular curves, or n-folding t-curves, obtained by folding n times a strip of paper in 3, each time possibly left then right or right then left, and unfolding it with π/3 angles. An example is the well known terdragon curve. They are self-avoiding like n-folding curves obtained by folding n times a strip of paper in two, each time possibly left or right, and unfolding it with π/2 angles. We also consider complete folding t-curves, which are the curves without endpoint obtained as inductive limits of n-folding t-curves. We show that each of them can be extended into a unique covering of the plane by disjoint such curves, and this covering satisfies the local isomorphism property introduced to investigate aperiodic tiling systems. Two coverings are locally isomorphic if and only if they are associated to the same sequence of foldings. Each class of locally isomorphic coverings contains exactly 2 ω (resp. 2 ω , 2 or 5, 0) isomorphism classes of coverings by 1 (resp. 2, 3, ≥ 4) curves. These properties are partly similar to those of complete folding curves.

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Paperfolding sequences, paperfolding curves and local isomorphism

Cited by 3 publications

References 7 publications

The number of paperfolding curves in a covering of the plane

The number of paperfolding curves in a covering of the plane

Peano-Gosper curves and the local isomorphism property

Self-avoiding and plane-filling properties for terdragons and other triangular folding curves

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