Amorphic complexity

Fuhrmann, Gabriel; Gröger, Maik; Jäger, Tobias

doi:10.1088/0951-7715/29/2/528

Cited by 21 publications

(23 citation statements)

References 70 publications

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“…Theorem 3.1 ( [FGJ16]). If a dynamical system (X, f ) has positive topological entropy or is weakly mixing with respect to some invariant probability measure µ with non-trivial support, then (X, f ) has infinite separation numbers.…”

Section: Asymptotic Separation Numbers and Amorphic Complexitymentioning

confidence: 99%

“…We refer the reader to [FGJ16] for an in-depth discussion of amorphic complexity and several classes of examples. However, the following statement is worth recalling.…”

Section: Asymptotic Separation Numbers and Amorphic Complexitymentioning

confidence: 99%

“…In this article we provide this kind of relation for the topological notion of amorphic complexity which was recently introduced in [FGJ16] to study dynamical systems with zero entropy. More precisely, we show that amorphic complexity of symbolic systems coincides with the box dimension of an associated subset in the so-called Besicovitch space of (A Z , σ) endowed with a canonical metric, see Lemma 6.2 and Theorem 6.5.…”

Section: Introductionmentioning

confidence: 99%

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Constant length substitutions, iterated function systems and amorphic complexity

Fuhrmann

Gröger

2019

Math. Z.

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We show how geometric methods from the general theory of fractal dimensions and iterated function systems can be deployed to study symbolic dynamics in the zero entropy regime. More precisely, we establish a dimensional characterization of the topological notion of amorphic complexity. For subshifts with discrete spectrum associated to constant length substitutions, this characterization allows us to derive bounds for the amorphic complexity by interpreting the subshift as the attractor of an iterated function system in a suitable quotient space. As a result, we obtain the general finiteness and positivity of amorphic complexity in this setting and provide a closed formula in case of a binary alphabet.

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Section: Asymptotic Separation Numbers and Amorphic Complexitymentioning

confidence: 99%

“…We refer the reader to [FGJ16] for an in-depth discussion of amorphic complexity and several classes of examples. However, the following statement is worth recalling.…”

Section: Asymptotic Separation Numbers and Amorphic Complexitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Constant length substitutions, iterated function systems and amorphic complexity

Fuhrmann

Gröger

2019

Math. Z.

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“…Otherwise, it is again possible to define an upper and a lower amorphic complexity. Basic properties of this quantity, like topological invariance, factor relations, power invariance and a product rule, as well as the application to a number of example classes are discussed in [FGJ15]. Somewhat surprisingly, amorphic complexity turns out be very well applicable and accessible to explicit computations in various system classes like regular Toeplitz flows, Sturmian shifts and Denjoy type circle homeomorphisms or cut and project quasicrystals.…”

Section: Power Entropy Modified Power Entropy and Amorphic Complexitymentioning

confidence: 99%

“…In this context, we also introduce and discuss amorphic complexity. This is a new topological invariant that equally measures the complexity of zero entropy systems, but is based on an asymptotic rather than a finite-time concept of separation [FGJ15].…”

Section: Introductionmentioning

confidence: 99%

Some remarks on modified power entropy

Gröger

Jäger

2016

Dynamics and Numbers

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The aim of this note is to point out some observations concerning modified power entropy of Z-and N-actions. First, we provide an elementary example showing that this quantity is sensitive to transient dynamics, and therefore does not satisfy a variational principle. Further, we show that modified power entropy is not suitable to detect the break of equicontinuity which takes place during the transition from almost periodic to almost automorphic minimal systems. In this respect, it differs from power entropy and amorphic complexity, which are two further topological invariants for zero entropy systems ('slow entropies'). Finally, we construct an example of an irregular Toeplitz flow with zero modified power entropy.

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Generic points for dynamical systems with average shadowing

2016

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We study the Besicovitch pseudometric D B for compact dynamical systems. The set of generic points of ergodic measures turns out to be closed with respect to D B . It is proved that the weak specification property implies the average asymptotic shadowing property and the latter property does not imply the former one nor the almost specification property. Furthermore an example of a proximal system with the average shadowing property is constructed. It is proved that to every invariant measure µ of a compact dynamical system one can associate a certain asymptotic pseudo orbit such that any point asymptotically tracing in average that pseudo orbit is generic for µ. A simple consequence of the theory presented is that every invariant measure has a generic point in a system with the asymptotic average shadowing property.

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Amorphic complexity

Cited by 21 publications

References 70 publications

Constant length substitutions, iterated function systems and amorphic complexity

Constant length substitutions, iterated function systems and amorphic complexity

Some remarks on modified power entropy

Generic points for dynamical systems with average shadowing

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